//===--- RewriteObjC.cpp - Playground for the code rewriter ---------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Hacks and fun related to the code rewriter. // //===----------------------------------------------------------------------===// #include "clang/Rewrite/Frontend/ASTConsumers.h" #include "clang/AST/AST.h" #include "clang/AST/ASTConsumer.h" #include "clang/AST/Attr.h" #include "clang/AST/ParentMap.h" #include "clang/Basic/CharInfo.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/IdentifierTable.h" #include "clang/Basic/SourceManager.h" #include "clang/Lex/Lexer.h" #include "clang/Rewrite/Core/Rewriter.h" #include "llvm/ADT/DenseSet.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/StringExtras.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/raw_ostream.h" #include <memory> #ifdef CLANG_ENABLE_OBJC_REWRITER using namespace clang; using llvm::utostr; namespace { class RewriteObjC : public ASTConsumer { protected: enum { BLOCK_FIELD_IS_OBJECT = 3, /* id, NSObject, __attribute__((NSObject)), block, ... */ BLOCK_FIELD_IS_BLOCK = 7, /* a block variable */ BLOCK_FIELD_IS_BYREF = 8, /* the on stack structure holding the __block variable */ BLOCK_FIELD_IS_WEAK = 16, /* declared __weak, only used in byref copy helpers */ BLOCK_BYREF_CALLER = 128, /* called from __block (byref) copy/dispose support routines */ BLOCK_BYREF_CURRENT_MAX = 256 }; enum { BLOCK_NEEDS_FREE = (1 << 24), BLOCK_HAS_COPY_DISPOSE = (1 << 25), BLOCK_HAS_CXX_OBJ = (1 << 26), BLOCK_IS_GC = (1 << 27), BLOCK_IS_GLOBAL = (1 << 28), BLOCK_HAS_DESCRIPTOR = (1 << 29) }; static const int OBJC_ABI_VERSION = 7; Rewriter Rewrite; DiagnosticsEngine &Diags; const LangOptions &LangOpts; ASTContext *Context; SourceManager *SM; TranslationUnitDecl *TUDecl; FileID MainFileID; const char *MainFileStart, *MainFileEnd; Stmt *CurrentBody; ParentMap *PropParentMap; // created lazily. std::string InFileName; raw_ostream* OutFile; std::string Preamble; TypeDecl *ProtocolTypeDecl; VarDecl *GlobalVarDecl; unsigned RewriteFailedDiag; // ObjC string constant support. unsigned NumObjCStringLiterals; VarDecl *ConstantStringClassReference; RecordDecl *NSStringRecord; // ObjC foreach break/continue generation support. int BcLabelCount; unsigned TryFinallyContainsReturnDiag; // Needed for super. ObjCMethodDecl *CurMethodDef; RecordDecl *SuperStructDecl; RecordDecl *ConstantStringDecl; FunctionDecl *MsgSendFunctionDecl; FunctionDecl *MsgSendSuperFunctionDecl; FunctionDecl *MsgSendStretFunctionDecl; FunctionDecl *MsgSendSuperStretFunctionDecl; FunctionDecl *MsgSendFpretFunctionDecl; FunctionDecl *GetClassFunctionDecl; FunctionDecl *GetMetaClassFunctionDecl; FunctionDecl *GetSuperClassFunctionDecl; FunctionDecl *SelGetUidFunctionDecl; FunctionDecl *CFStringFunctionDecl; FunctionDecl *SuperConstructorFunctionDecl; FunctionDecl *CurFunctionDef; FunctionDecl *CurFunctionDeclToDeclareForBlock; /* Misc. containers needed for meta-data rewrite. */ SmallVector<ObjCImplementationDecl *, 8> ClassImplementation; SmallVector<ObjCCategoryImplDecl *, 8> CategoryImplementation; llvm::SmallPtrSet<ObjCInterfaceDecl*, 8> ObjCSynthesizedStructs; llvm::SmallPtrSet<ObjCProtocolDecl*, 8> ObjCSynthesizedProtocols; llvm::SmallPtrSet<ObjCInterfaceDecl*, 8> ObjCForwardDecls; llvm::DenseMap<ObjCMethodDecl*, std::string> MethodInternalNames; SmallVector<Stmt *, 32> Stmts; SmallVector<int, 8> ObjCBcLabelNo; // Remember all the @protocol(<expr>) expressions. llvm::SmallPtrSet<ObjCProtocolDecl *, 32> ProtocolExprDecls; llvm::DenseSet<uint64_t> CopyDestroyCache; // Block expressions. SmallVector<BlockExpr *, 32> Blocks; SmallVector<int, 32> InnerDeclRefsCount; SmallVector<DeclRefExpr *, 32> InnerDeclRefs; SmallVector<DeclRefExpr *, 32> BlockDeclRefs; // Block related declarations. SmallVector<ValueDecl *, 8> BlockByCopyDecls; llvm::SmallPtrSet<ValueDecl *, 8> BlockByCopyDeclsPtrSet; SmallVector<ValueDecl *, 8> BlockByRefDecls; llvm::SmallPtrSet<ValueDecl *, 8> BlockByRefDeclsPtrSet; llvm::DenseMap<ValueDecl *, unsigned> BlockByRefDeclNo; llvm::SmallPtrSet<ValueDecl *, 8> ImportedBlockDecls; llvm::SmallPtrSet<VarDecl *, 8> ImportedLocalExternalDecls; llvm::DenseMap<BlockExpr *, std::string> RewrittenBlockExprs; // This maps an original source AST to it's rewritten form. This allows // us to avoid rewriting the same node twice (which is very uncommon). // This is needed to support some of the exotic property rewriting. llvm::DenseMap<Stmt *, Stmt *> ReplacedNodes; // Needed for header files being rewritten bool IsHeader; bool SilenceRewriteMacroWarning; bool objc_impl_method; bool DisableReplaceStmt; class DisableReplaceStmtScope { RewriteObjC &R; bool SavedValue; public: DisableReplaceStmtScope(RewriteObjC &R) : R(R), SavedValue(R.DisableReplaceStmt) { R.DisableReplaceStmt = true; } ~DisableReplaceStmtScope() { R.DisableReplaceStmt = SavedValue; } }; void InitializeCommon(ASTContext &context); public: // Top Level Driver code. bool HandleTopLevelDecl(DeclGroupRef D) override { for (DeclGroupRef::iterator I = D.begin(), E = D.end(); I != E; ++I) { if (ObjCInterfaceDecl *Class = dyn_cast<ObjCInterfaceDecl>(*I)) { if (!Class->isThisDeclarationADefinition()) { RewriteForwardClassDecl(D); break; } } if (ObjCProtocolDecl *Proto = dyn_cast<ObjCProtocolDecl>(*I)) { if (!Proto->isThisDeclarationADefinition()) { RewriteForwardProtocolDecl(D); break; } } HandleTopLevelSingleDecl(*I); } return true; } void HandleTopLevelSingleDecl(Decl *D); void HandleDeclInMainFile(Decl *D); RewriteObjC(std::string inFile, raw_ostream *OS, DiagnosticsEngine &D, const LangOptions &LOpts, bool silenceMacroWarn); ~RewriteObjC() override {} void HandleTranslationUnit(ASTContext &C) override; void ReplaceStmt(Stmt *Old, Stmt *New) { ReplaceStmtWithRange(Old, New, Old->getSourceRange()); } void ReplaceStmtWithRange(Stmt *Old, Stmt *New, SourceRange SrcRange) { assert(Old != nullptr && New != nullptr && "Expected non-null Stmt's"); Stmt *ReplacingStmt = ReplacedNodes[Old]; if (ReplacingStmt) return; // We can't rewrite the same node twice. if (DisableReplaceStmt) return; // Measure the old text. int Size = Rewrite.getRangeSize(SrcRange); if (Size == -1) { Diags.Report(Context->getFullLoc(Old->getLocStart()), RewriteFailedDiag) << Old->getSourceRange(); return; } // Get the new text. std::string SStr; llvm::raw_string_ostream S(SStr); New->printPretty(S, nullptr, PrintingPolicy(LangOpts)); const std::string &Str = S.str(); // If replacement succeeded or warning disabled return with no warning. if (!Rewrite.ReplaceText(SrcRange.getBegin(), Size, Str)) { ReplacedNodes[Old] = New; return; } if (SilenceRewriteMacroWarning) return; Diags.Report(Context->getFullLoc(Old->getLocStart()), RewriteFailedDiag) << Old->getSourceRange(); } void InsertText(SourceLocation Loc, StringRef Str, bool InsertAfter = true) { // If insertion succeeded or warning disabled return with no warning. if (!Rewrite.InsertText(Loc, Str, InsertAfter) || SilenceRewriteMacroWarning) return; Diags.Report(Context->getFullLoc(Loc), RewriteFailedDiag); } void ReplaceText(SourceLocation Start, unsigned OrigLength, StringRef Str) { // If removal succeeded or warning disabled return with no warning. if (!Rewrite.ReplaceText(Start, OrigLength, Str) || SilenceRewriteMacroWarning) return; Diags.Report(Context->getFullLoc(Start), RewriteFailedDiag); } // Syntactic Rewriting. void RewriteRecordBody(RecordDecl *RD); void RewriteInclude(); void RewriteForwardClassDecl(DeclGroupRef D); void RewriteForwardClassDecl(const SmallVectorImpl<Decl *> &DG); void RewriteForwardClassEpilogue(ObjCInterfaceDecl *ClassDecl, const std::string &typedefString); void RewriteImplementations(); void RewritePropertyImplDecl(ObjCPropertyImplDecl *PID, ObjCImplementationDecl *IMD, ObjCCategoryImplDecl *CID); void RewriteInterfaceDecl(ObjCInterfaceDecl *Dcl); void RewriteImplementationDecl(Decl *Dcl); void RewriteObjCMethodDecl(const ObjCInterfaceDecl *IDecl, ObjCMethodDecl *MDecl, std::string &ResultStr); void RewriteTypeIntoString(QualType T, std::string &ResultStr, const FunctionType *&FPRetType); void RewriteByRefString(std::string &ResultStr, const std::string &Name, ValueDecl *VD, bool def=false); void RewriteCategoryDecl(ObjCCategoryDecl *Dcl); void RewriteProtocolDecl(ObjCProtocolDecl *Dcl); void RewriteForwardProtocolDecl(DeclGroupRef D); void RewriteForwardProtocolDecl(const SmallVectorImpl<Decl *> &DG); void RewriteMethodDeclaration(ObjCMethodDecl *Method); void RewriteProperty(ObjCPropertyDecl *prop); void RewriteFunctionDecl(FunctionDecl *FD); void RewriteBlockPointerType(std::string& Str, QualType Type); void RewriteBlockPointerTypeVariable(std::string& Str, ValueDecl *VD); void RewriteBlockLiteralFunctionDecl(FunctionDecl *FD); void RewriteObjCQualifiedInterfaceTypes(Decl *Dcl); void RewriteTypeOfDecl(VarDecl *VD); void RewriteObjCQualifiedInterfaceTypes(Expr *E); // Expression Rewriting. Stmt *RewriteFunctionBodyOrGlobalInitializer(Stmt *S); Stmt *RewriteAtEncode(ObjCEncodeExpr *Exp); Stmt *RewritePropertyOrImplicitGetter(PseudoObjectExpr *Pseudo); Stmt *RewritePropertyOrImplicitSetter(PseudoObjectExpr *Pseudo); Stmt *RewriteAtSelector(ObjCSelectorExpr *Exp); Stmt *RewriteMessageExpr(ObjCMessageExpr *Exp); Stmt *RewriteObjCStringLiteral(ObjCStringLiteral *Exp); Stmt *RewriteObjCProtocolExpr(ObjCProtocolExpr *Exp); void RewriteTryReturnStmts(Stmt *S); void RewriteSyncReturnStmts(Stmt *S, std::string buf); Stmt *RewriteObjCTryStmt(ObjCAtTryStmt *S); Stmt *RewriteObjCSynchronizedStmt(ObjCAtSynchronizedStmt *S); Stmt *RewriteObjCThrowStmt(ObjCAtThrowStmt *S); Stmt *RewriteObjCForCollectionStmt(ObjCForCollectionStmt *S, SourceLocation OrigEnd); Stmt *RewriteBreakStmt(BreakStmt *S); Stmt *RewriteContinueStmt(ContinueStmt *S); void RewriteCastExpr(CStyleCastExpr *CE); // Block rewriting. void RewriteBlocksInFunctionProtoType(QualType funcType, NamedDecl *D); // Block specific rewrite rules. void RewriteBlockPointerDecl(NamedDecl *VD); void RewriteByRefVar(VarDecl *VD); Stmt *RewriteBlockDeclRefExpr(DeclRefExpr *VD); Stmt *RewriteLocalVariableExternalStorage(DeclRefExpr *DRE); void RewriteBlockPointerFunctionArgs(FunctionDecl *FD); void RewriteObjCInternalStruct(ObjCInterfaceDecl *CDecl, std::string &Result); void Initialize(ASTContext &context) override = 0; // Metadata Rewriting. virtual void RewriteMetaDataIntoBuffer(std::string &Result) = 0; virtual void RewriteObjCProtocolListMetaData(const ObjCList<ObjCProtocolDecl> &Prots, StringRef prefix, StringRef ClassName, std::string &Result) = 0; virtual void RewriteObjCCategoryImplDecl(ObjCCategoryImplDecl *CDecl, std::string &Result) = 0; virtual void RewriteObjCProtocolMetaData(ObjCProtocolDecl *Protocol, StringRef prefix, StringRef ClassName, std::string &Result) = 0; virtual void RewriteObjCClassMetaData(ObjCImplementationDecl *IDecl, std::string &Result) = 0; // Rewriting ivar access virtual Stmt *RewriteObjCIvarRefExpr(ObjCIvarRefExpr *IV) = 0; virtual void RewriteIvarOffsetComputation(ObjCIvarDecl *ivar, std::string &Result) = 0; // Misc. AST transformation routines. Sometimes they end up calling // rewriting routines on the new ASTs. CallExpr *SynthesizeCallToFunctionDecl(FunctionDecl *FD, Expr **args, unsigned nargs, SourceLocation StartLoc=SourceLocation(), SourceLocation EndLoc=SourceLocation()); CallExpr *SynthMsgSendStretCallExpr(FunctionDecl *MsgSendStretFlavor, QualType msgSendType, QualType returnType, SmallVectorImpl<QualType> &ArgTypes, SmallVectorImpl<Expr*> &MsgExprs, ObjCMethodDecl *Method); Stmt *SynthMessageExpr(ObjCMessageExpr *Exp, SourceLocation StartLoc=SourceLocation(), SourceLocation EndLoc=SourceLocation()); void SynthCountByEnumWithState(std::string &buf); void SynthMsgSendFunctionDecl(); void SynthMsgSendSuperFunctionDecl(); void SynthMsgSendStretFunctionDecl(); void SynthMsgSendFpretFunctionDecl(); void SynthMsgSendSuperStretFunctionDecl(); void SynthGetClassFunctionDecl(); void SynthGetMetaClassFunctionDecl(); void SynthGetSuperClassFunctionDecl(); void SynthSelGetUidFunctionDecl(); void SynthSuperConstructorFunctionDecl(); std::string SynthesizeByrefCopyDestroyHelper(VarDecl *VD, int flag); std::string SynthesizeBlockHelperFuncs(BlockExpr *CE, int i, StringRef funcName, std::string Tag); std::string SynthesizeBlockFunc(BlockExpr *CE, int i, StringRef funcName, std::string Tag); std::string SynthesizeBlockImpl(BlockExpr *CE, std::string Tag, std::string Desc); std::string SynthesizeBlockDescriptor(std::string DescTag, std::string ImplTag, int i, StringRef funcName, unsigned hasCopy); Stmt *SynthesizeBlockCall(CallExpr *Exp, const Expr* BlockExp); void SynthesizeBlockLiterals(SourceLocation FunLocStart, StringRef FunName); FunctionDecl *SynthBlockInitFunctionDecl(StringRef name); Stmt *SynthBlockInitExpr(BlockExpr *Exp, const SmallVectorImpl<DeclRefExpr *> &InnerBlockDeclRefs); // Misc. helper routines. QualType getProtocolType(); void WarnAboutReturnGotoStmts(Stmt *S); void HasReturnStmts(Stmt *S, bool &hasReturns); void CheckFunctionPointerDecl(QualType dType, NamedDecl *ND); void InsertBlockLiteralsWithinFunction(FunctionDecl *FD); void InsertBlockLiteralsWithinMethod(ObjCMethodDecl *MD); bool IsDeclStmtInForeachHeader(DeclStmt *DS); void CollectBlockDeclRefInfo(BlockExpr *Exp); void GetBlockDeclRefExprs(Stmt *S); void GetInnerBlockDeclRefExprs(Stmt *S, SmallVectorImpl<DeclRefExpr *> &InnerBlockDeclRefs, llvm::SmallPtrSetImpl<const DeclContext *> &InnerContexts); // We avoid calling Type::isBlockPointerType(), since it operates on the // canonical type. We only care if the top-level type is a closure pointer. bool isTopLevelBlockPointerType(QualType T) { return isa<BlockPointerType>(T); } /// convertBlockPointerToFunctionPointer - Converts a block-pointer type /// to a function pointer type and upon success, returns true; false /// otherwise. bool convertBlockPointerToFunctionPointer(QualType &T) { if (isTopLevelBlockPointerType(T)) { const BlockPointerType *BPT = T->getAs<BlockPointerType>(); T = Context->getPointerType(BPT->getPointeeType()); return true; } return false; } bool needToScanForQualifiers(QualType T); QualType getSuperStructType(); QualType getConstantStringStructType(); QualType convertFunctionTypeOfBlocks(const FunctionType *FT); bool BufferContainsPPDirectives(const char *startBuf, const char *endBuf); void convertToUnqualifiedObjCType(QualType &T) { if (T->isObjCQualifiedIdType()) T = Context->getObjCIdType(); else if (T->isObjCQualifiedClassType()) T = Context->getObjCClassType(); else if (T->isObjCObjectPointerType() && T->getPointeeType()->isObjCQualifiedInterfaceType()) { if (const ObjCObjectPointerType * OBJPT = T->getAsObjCInterfacePointerType()) { const ObjCInterfaceType *IFaceT = OBJPT->getInterfaceType(); T = QualType(IFaceT, 0); T = Context->getPointerType(T); } } } // FIXME: This predicate seems like it would be useful to add to ASTContext. bool isObjCType(QualType T) { if (!LangOpts.ObjC1 && !LangOpts.ObjC2) return false; QualType OCT = Context->getCanonicalType(T).getUnqualifiedType(); if (OCT == Context->getCanonicalType(Context->getObjCIdType()) || OCT == Context->getCanonicalType(Context->getObjCClassType())) return true; if (const PointerType *PT = OCT->getAs<PointerType>()) { if (isa<ObjCInterfaceType>(PT->getPointeeType()) || PT->getPointeeType()->isObjCQualifiedIdType()) return true; } return false; } bool PointerTypeTakesAnyBlockArguments(QualType QT); bool PointerTypeTakesAnyObjCQualifiedType(QualType QT); void GetExtentOfArgList(const char *Name, const char *&LParen, const char *&RParen); void QuoteDoublequotes(std::string &From, std::string &To) { for (unsigned i = 0; i < From.length(); i++) { if (From[i] == '"') To += "\\\""; else To += From[i]; } } QualType getSimpleFunctionType(QualType result, ArrayRef<QualType> args, bool variadic = false) { if (result == Context->getObjCInstanceType()) result = Context->getObjCIdType(); FunctionProtoType::ExtProtoInfo fpi; fpi.Variadic = variadic; return Context->getFunctionType(result, args, fpi); } // Helper function: create a CStyleCastExpr with trivial type source info. CStyleCastExpr* NoTypeInfoCStyleCastExpr(ASTContext *Ctx, QualType Ty, CastKind Kind, Expr *E) { TypeSourceInfo *TInfo = Ctx->getTrivialTypeSourceInfo(Ty, SourceLocation()); return CStyleCastExpr::Create(*Ctx, Ty, VK_RValue, Kind, E, nullptr, TInfo, SourceLocation(), SourceLocation()); } StringLiteral *getStringLiteral(StringRef Str) { QualType StrType = Context->getConstantArrayType( Context->CharTy, llvm::APInt(32, Str.size() + 1), ArrayType::Normal, 0); return StringLiteral::Create(*Context, Str, StringLiteral::Ascii, /*Pascal=*/false, StrType, SourceLocation()); } }; class RewriteObjCFragileABI : public RewriteObjC { public: RewriteObjCFragileABI(std::string inFile, raw_ostream *OS, DiagnosticsEngine &D, const LangOptions &LOpts, bool silenceMacroWarn) : RewriteObjC(inFile, OS, D, LOpts, silenceMacroWarn) {} ~RewriteObjCFragileABI() override {} void Initialize(ASTContext &context) override; // Rewriting metadata template<typename MethodIterator> void RewriteObjCMethodsMetaData(MethodIterator MethodBegin, MethodIterator MethodEnd, bool IsInstanceMethod, StringRef prefix, StringRef ClassName, std::string &Result); void RewriteObjCProtocolMetaData(ObjCProtocolDecl *Protocol, StringRef prefix, StringRef ClassName, std::string &Result) override; void RewriteObjCProtocolListMetaData( const ObjCList<ObjCProtocolDecl> &Prots, StringRef prefix, StringRef ClassName, std::string &Result) override; void RewriteObjCClassMetaData(ObjCImplementationDecl *IDecl, std::string &Result) override; void RewriteMetaDataIntoBuffer(std::string &Result) override; void RewriteObjCCategoryImplDecl(ObjCCategoryImplDecl *CDecl, std::string &Result) override; // Rewriting ivar void RewriteIvarOffsetComputation(ObjCIvarDecl *ivar, std::string &Result) override; Stmt *RewriteObjCIvarRefExpr(ObjCIvarRefExpr *IV) override; }; } void RewriteObjC::RewriteBlocksInFunctionProtoType(QualType funcType, NamedDecl *D) { if (const FunctionProtoType *fproto = dyn_cast<FunctionProtoType>(funcType.IgnoreParens())) { for (const auto &I : fproto->param_types()) if (isTopLevelBlockPointerType(I)) { // All the args are checked/rewritten. Don't call twice! RewriteBlockPointerDecl(D); break; } } } void RewriteObjC::CheckFunctionPointerDecl(QualType funcType, NamedDecl *ND) { const PointerType *PT = funcType->getAs<PointerType>(); if (PT && PointerTypeTakesAnyBlockArguments(funcType)) RewriteBlocksInFunctionProtoType(PT->getPointeeType(), ND); } static bool IsHeaderFile(const std::string &Filename) { std::string::size_type DotPos = Filename.rfind('.'); if (DotPos == std::string::npos) { // no file extension return false; } std::string Ext = std::string(Filename.begin()+DotPos+1, Filename.end()); // C header: .h // C++ header: .hh or .H; return Ext == "h" || Ext == "hh" || Ext == "H"; } RewriteObjC::RewriteObjC(std::string inFile, raw_ostream* OS, DiagnosticsEngine &D, const LangOptions &LOpts, bool silenceMacroWarn) : Diags(D), LangOpts(LOpts), InFileName(inFile), OutFile(OS), SilenceRewriteMacroWarning(silenceMacroWarn) { IsHeader = IsHeaderFile(inFile); RewriteFailedDiag = Diags.getCustomDiagID(DiagnosticsEngine::Warning, "rewriting sub-expression within a macro (may not be correct)"); TryFinallyContainsReturnDiag = Diags.getCustomDiagID( DiagnosticsEngine::Warning, "rewriter doesn't support user-specified control flow semantics " "for @try/@finally (code may not execute properly)"); } std::unique_ptr<ASTConsumer> clang::CreateObjCRewriter(const std::string &InFile, raw_ostream *OS, DiagnosticsEngine &Diags, const LangOptions &LOpts, bool SilenceRewriteMacroWarning) { return llvm::make_unique<RewriteObjCFragileABI>(InFile, OS, Diags, LOpts, SilenceRewriteMacroWarning); } void RewriteObjC::InitializeCommon(ASTContext &context) { Context = &context; SM = &Context->getSourceManager(); TUDecl = Context->getTranslationUnitDecl(); MsgSendFunctionDecl = nullptr; MsgSendSuperFunctionDecl = nullptr; MsgSendStretFunctionDecl = nullptr; MsgSendSuperStretFunctionDecl = nullptr; MsgSendFpretFunctionDecl = nullptr; GetClassFunctionDecl = nullptr; GetMetaClassFunctionDecl = nullptr; GetSuperClassFunctionDecl = nullptr; SelGetUidFunctionDecl = nullptr; CFStringFunctionDecl = nullptr; ConstantStringClassReference = nullptr; NSStringRecord = nullptr; CurMethodDef = nullptr; CurFunctionDef = nullptr; CurFunctionDeclToDeclareForBlock = nullptr; GlobalVarDecl = nullptr; SuperStructDecl = nullptr; ProtocolTypeDecl = nullptr; ConstantStringDecl = nullptr; BcLabelCount = 0; SuperConstructorFunctionDecl = nullptr; NumObjCStringLiterals = 0; PropParentMap = nullptr; CurrentBody = nullptr; DisableReplaceStmt = false; objc_impl_method = false; // Get the ID and start/end of the main file. MainFileID = SM->getMainFileID(); const llvm::MemoryBuffer *MainBuf = SM->getBuffer(MainFileID); MainFileStart = MainBuf->getBufferStart(); MainFileEnd = MainBuf->getBufferEnd(); Rewrite.setSourceMgr(Context->getSourceManager(), Context->getLangOpts()); } //===----------------------------------------------------------------------===// // Top Level Driver Code //===----------------------------------------------------------------------===// void RewriteObjC::HandleTopLevelSingleDecl(Decl *D) { if (Diags.hasErrorOccurred()) return; // Two cases: either the decl could be in the main file, or it could be in a // #included file. If the former, rewrite it now. If the later, check to see // if we rewrote the #include/#import. SourceLocation Loc = D->getLocation(); Loc = SM->getExpansionLoc(Loc); // If this is for a builtin, ignore it. if (Loc.isInvalid()) return; // Look for built-in declarations that we need to refer during the rewrite. if (FunctionDecl *FD = dyn_cast<FunctionDecl>(D)) { RewriteFunctionDecl(FD); } else if (VarDecl *FVD = dyn_cast<VarDecl>(D)) { // declared in <Foundation/NSString.h> if (FVD->getName() == "_NSConstantStringClassReference") { ConstantStringClassReference = FVD; return; } } else if (ObjCInterfaceDecl *ID = dyn_cast<ObjCInterfaceDecl>(D)) { if (ID->isThisDeclarationADefinition()) RewriteInterfaceDecl(ID); } else if (ObjCCategoryDecl *CD = dyn_cast<ObjCCategoryDecl>(D)) { RewriteCategoryDecl(CD); } else if (ObjCProtocolDecl *PD = dyn_cast<ObjCProtocolDecl>(D)) { if (PD->isThisDeclarationADefinition()) RewriteProtocolDecl(PD); } else if (LinkageSpecDecl *LSD = dyn_cast<LinkageSpecDecl>(D)) { // Recurse into linkage specifications for (DeclContext::decl_iterator DI = LSD->decls_begin(), DIEnd = LSD->decls_end(); DI != DIEnd; ) { if (ObjCInterfaceDecl *IFace = dyn_cast<ObjCInterfaceDecl>((*DI))) { if (!IFace->isThisDeclarationADefinition()) { SmallVector<Decl *, 8> DG; SourceLocation StartLoc = IFace->getLocStart(); do { if (isa<ObjCInterfaceDecl>(*DI) && !cast<ObjCInterfaceDecl>(*DI)->isThisDeclarationADefinition() && StartLoc == (*DI)->getLocStart()) DG.push_back(*DI); else break; ++DI; } while (DI != DIEnd); RewriteForwardClassDecl(DG); continue; } } if (ObjCProtocolDecl *Proto = dyn_cast<ObjCProtocolDecl>((*DI))) { if (!Proto->isThisDeclarationADefinition()) { SmallVector<Decl *, 8> DG; SourceLocation StartLoc = Proto->getLocStart(); do { if (isa<ObjCProtocolDecl>(*DI) && !cast<ObjCProtocolDecl>(*DI)->isThisDeclarationADefinition() && StartLoc == (*DI)->getLocStart()) DG.push_back(*DI); else break; ++DI; } while (DI != DIEnd); RewriteForwardProtocolDecl(DG); continue; } } HandleTopLevelSingleDecl(*DI); ++DI; } } // If we have a decl in the main file, see if we should rewrite it. if (SM->isWrittenInMainFile(Loc)) return HandleDeclInMainFile(D); } //===----------------------------------------------------------------------===// // Syntactic (non-AST) Rewriting Code //===----------------------------------------------------------------------===// void RewriteObjC::RewriteInclude() { SourceLocation LocStart = SM->getLocForStartOfFile(MainFileID); StringRef MainBuf = SM->getBufferData(MainFileID); const char *MainBufStart = MainBuf.begin(); const char *MainBufEnd = MainBuf.end(); size_t ImportLen = strlen("import"); // Loop over the whole file, looking for includes. for (const char *BufPtr = MainBufStart; BufPtr < MainBufEnd; ++BufPtr) { if (*BufPtr == '#') { if (++BufPtr == MainBufEnd) return; while (*BufPtr == ' ' || *BufPtr == '\t') if (++BufPtr == MainBufEnd) return; if (!strncmp(BufPtr, "import", ImportLen)) { // replace import with include SourceLocation ImportLoc = LocStart.getLocWithOffset(BufPtr-MainBufStart); ReplaceText(ImportLoc, ImportLen, "include"); BufPtr += ImportLen; } } } } static std::string getIvarAccessString(ObjCIvarDecl *OID) { const ObjCInterfaceDecl *ClassDecl = OID->getContainingInterface(); std::string S; S = "((struct "; S += ClassDecl->getIdentifier()->getName(); S += "_IMPL *)self)->"; S += OID->getName(); return S; } void RewriteObjC::RewritePropertyImplDecl(ObjCPropertyImplDecl *PID, ObjCImplementationDecl *IMD, ObjCCategoryImplDecl *CID) { static bool objcGetPropertyDefined = false; static bool objcSetPropertyDefined = false; SourceLocation startLoc = PID->getLocStart(); InsertText(startLoc, "// "); const char *startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @synthesize location"); const char *semiBuf = strchr(startBuf, ';'); assert((*semiBuf == ';') && "@synthesize: can't find ';'"); SourceLocation onePastSemiLoc = startLoc.getLocWithOffset(semiBuf-startBuf+1); if (PID->getPropertyImplementation() == ObjCPropertyImplDecl::Dynamic) return; // FIXME: is this correct? // Generate the 'getter' function. ObjCPropertyDecl *PD = PID->getPropertyDecl(); ObjCIvarDecl *OID = PID->getPropertyIvarDecl(); if (!OID) return; unsigned Attributes = PD->getPropertyAttributes(); if (!PD->getGetterMethodDecl()->isDefined()) { bool GenGetProperty = !(Attributes & ObjCPropertyDecl::OBJC_PR_nonatomic) && (Attributes & (ObjCPropertyDecl::OBJC_PR_retain | ObjCPropertyDecl::OBJC_PR_copy)); std::string Getr; if (GenGetProperty && !objcGetPropertyDefined) { objcGetPropertyDefined = true; // FIXME. Is this attribute correct in all cases? Getr = "\nextern \"C\" __declspec(dllimport) " "id objc_getProperty(id, SEL, long, bool);\n"; } RewriteObjCMethodDecl(OID->getContainingInterface(), PD->getGetterMethodDecl(), Getr); Getr += "{ "; // Synthesize an explicit cast to gain access to the ivar. // See objc-act.c:objc_synthesize_new_getter() for details. if (GenGetProperty) { // return objc_getProperty(self, _cmd, offsetof(ClassDecl, OID), 1) Getr += "typedef "; const FunctionType *FPRetType = nullptr; RewriteTypeIntoString(PD->getGetterMethodDecl()->getReturnType(), Getr, FPRetType); Getr += " _TYPE"; if (FPRetType) { Getr += ")"; // close the precedence "scope" for "*". // Now, emit the argument types (if any). if (const FunctionProtoType *FT = dyn_cast<FunctionProtoType>(FPRetType)){ Getr += "("; for (unsigned i = 0, e = FT->getNumParams(); i != e; ++i) { if (i) Getr += ", "; std::string ParamStr = FT->getParamType(i).getAsString(Context->getPrintingPolicy()); Getr += ParamStr; } if (FT->isVariadic()) { if (FT->getNumParams()) Getr += ", "; Getr += "..."; } Getr += ")"; } else Getr += "()"; } Getr += ";\n"; Getr += "return (_TYPE)"; Getr += "objc_getProperty(self, _cmd, "; RewriteIvarOffsetComputation(OID, Getr); Getr += ", 1)"; } else Getr += "return " + getIvarAccessString(OID); Getr += "; }"; InsertText(onePastSemiLoc, Getr); } if (PD->isReadOnly() || PD->getSetterMethodDecl()->isDefined()) return; // Generate the 'setter' function. std::string Setr; bool GenSetProperty = Attributes & (ObjCPropertyDecl::OBJC_PR_retain | ObjCPropertyDecl::OBJC_PR_copy); if (GenSetProperty && !objcSetPropertyDefined) { objcSetPropertyDefined = true; // FIXME. Is this attribute correct in all cases? Setr = "\nextern \"C\" __declspec(dllimport) " "void objc_setProperty (id, SEL, long, id, bool, bool);\n"; } RewriteObjCMethodDecl(OID->getContainingInterface(), PD->getSetterMethodDecl(), Setr); Setr += "{ "; // Synthesize an explicit cast to initialize the ivar. // See objc-act.c:objc_synthesize_new_setter() for details. if (GenSetProperty) { Setr += "objc_setProperty (self, _cmd, "; RewriteIvarOffsetComputation(OID, Setr); Setr += ", (id)"; Setr += PD->getName(); Setr += ", "; if (Attributes & ObjCPropertyDecl::OBJC_PR_nonatomic) Setr += "0, "; else Setr += "1, "; if (Attributes & ObjCPropertyDecl::OBJC_PR_copy) Setr += "1)"; else Setr += "0)"; } else { Setr += getIvarAccessString(OID) + " = "; Setr += PD->getName(); } Setr += "; }"; InsertText(onePastSemiLoc, Setr); } static void RewriteOneForwardClassDecl(ObjCInterfaceDecl *ForwardDecl, std::string &typedefString) { typedefString += "#ifndef _REWRITER_typedef_"; typedefString += ForwardDecl->getNameAsString(); typedefString += "\n"; typedefString += "#define _REWRITER_typedef_"; typedefString += ForwardDecl->getNameAsString(); typedefString += "\n"; typedefString += "typedef struct objc_object "; typedefString += ForwardDecl->getNameAsString(); typedefString += ";\n#endif\n"; } void RewriteObjC::RewriteForwardClassEpilogue(ObjCInterfaceDecl *ClassDecl, const std::string &typedefString) { SourceLocation startLoc = ClassDecl->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); const char *semiPtr = strchr(startBuf, ';'); // Replace the @class with typedefs corresponding to the classes. ReplaceText(startLoc, semiPtr-startBuf+1, typedefString); } void RewriteObjC::RewriteForwardClassDecl(DeclGroupRef D) { std::string typedefString; for (DeclGroupRef::iterator I = D.begin(), E = D.end(); I != E; ++I) { ObjCInterfaceDecl *ForwardDecl = cast<ObjCInterfaceDecl>(*I); if (I == D.begin()) { // Translate to typedef's that forward reference structs with the same name // as the class. As a convenience, we include the original declaration // as a comment. typedefString += "// @class "; typedefString += ForwardDecl->getNameAsString(); typedefString += ";\n"; } RewriteOneForwardClassDecl(ForwardDecl, typedefString); } DeclGroupRef::iterator I = D.begin(); RewriteForwardClassEpilogue(cast<ObjCInterfaceDecl>(*I), typedefString); } void RewriteObjC::RewriteForwardClassDecl(const SmallVectorImpl<Decl *> &D) { std::string typedefString; for (unsigned i = 0; i < D.size(); i++) { ObjCInterfaceDecl *ForwardDecl = cast<ObjCInterfaceDecl>(D[i]); if (i == 0) { typedefString += "// @class "; typedefString += ForwardDecl->getNameAsString(); typedefString += ";\n"; } RewriteOneForwardClassDecl(ForwardDecl, typedefString); } RewriteForwardClassEpilogue(cast<ObjCInterfaceDecl>(D[0]), typedefString); } void RewriteObjC::RewriteMethodDeclaration(ObjCMethodDecl *Method) { // When method is a synthesized one, such as a getter/setter there is // nothing to rewrite. if (Method->isImplicit()) return; SourceLocation LocStart = Method->getLocStart(); SourceLocation LocEnd = Method->getLocEnd(); if (SM->getExpansionLineNumber(LocEnd) > SM->getExpansionLineNumber(LocStart)) { InsertText(LocStart, "#if 0\n"); ReplaceText(LocEnd, 1, ";\n#endif\n"); } else { InsertText(LocStart, "// "); } } void RewriteObjC::RewriteProperty(ObjCPropertyDecl *prop) { SourceLocation Loc = prop->getAtLoc(); ReplaceText(Loc, 0, "// "); // FIXME: handle properties that are declared across multiple lines. } void RewriteObjC::RewriteCategoryDecl(ObjCCategoryDecl *CatDecl) { SourceLocation LocStart = CatDecl->getLocStart(); // FIXME: handle category headers that are declared across multiple lines. ReplaceText(LocStart, 0, "// "); for (auto *I : CatDecl->properties()) RewriteProperty(I); for (auto *I : CatDecl->instance_methods()) RewriteMethodDeclaration(I); for (auto *I : CatDecl->class_methods()) RewriteMethodDeclaration(I); // Lastly, comment out the @end. ReplaceText(CatDecl->getAtEndRange().getBegin(), strlen("@end"), "/* @end */"); } void RewriteObjC::RewriteProtocolDecl(ObjCProtocolDecl *PDecl) { SourceLocation LocStart = PDecl->getLocStart(); assert(PDecl->isThisDeclarationADefinition()); // FIXME: handle protocol headers that are declared across multiple lines. ReplaceText(LocStart, 0, "// "); for (auto *I : PDecl->instance_methods()) RewriteMethodDeclaration(I); for (auto *I : PDecl->class_methods()) RewriteMethodDeclaration(I); for (auto *I : PDecl->properties()) RewriteProperty(I); // Lastly, comment out the @end. SourceLocation LocEnd = PDecl->getAtEndRange().getBegin(); ReplaceText(LocEnd, strlen("@end"), "/* @end */"); // Must comment out @optional/@required const char *startBuf = SM->getCharacterData(LocStart); const char *endBuf = SM->getCharacterData(LocEnd); for (const char *p = startBuf; p < endBuf; p++) { if (*p == '@' && !strncmp(p+1, "optional", strlen("optional"))) { SourceLocation OptionalLoc = LocStart.getLocWithOffset(p-startBuf); ReplaceText(OptionalLoc, strlen("@optional"), "/* @optional */"); } else if (*p == '@' && !strncmp(p+1, "required", strlen("required"))) { SourceLocation OptionalLoc = LocStart.getLocWithOffset(p-startBuf); ReplaceText(OptionalLoc, strlen("@required"), "/* @required */"); } } } void RewriteObjC::RewriteForwardProtocolDecl(DeclGroupRef D) { SourceLocation LocStart = (*D.begin())->getLocStart(); if (LocStart.isInvalid()) llvm_unreachable("Invalid SourceLocation"); // FIXME: handle forward protocol that are declared across multiple lines. ReplaceText(LocStart, 0, "// "); } void RewriteObjC::RewriteForwardProtocolDecl(const SmallVectorImpl<Decl *> &DG) { SourceLocation LocStart = DG[0]->getLocStart(); if (LocStart.isInvalid()) llvm_unreachable("Invalid SourceLocation"); // FIXME: handle forward protocol that are declared across multiple lines. ReplaceText(LocStart, 0, "// "); } void RewriteObjC::RewriteTypeIntoString(QualType T, std::string &ResultStr, const FunctionType *&FPRetType) { if (T->isObjCQualifiedIdType()) ResultStr += "id"; else if (T->isFunctionPointerType() || T->isBlockPointerType()) { // needs special handling, since pointer-to-functions have special // syntax (where a decaration models use). QualType retType = T; QualType PointeeTy; if (const PointerType* PT = retType->getAs<PointerType>()) PointeeTy = PT->getPointeeType(); else if (const BlockPointerType *BPT = retType->getAs<BlockPointerType>()) PointeeTy = BPT->getPointeeType(); if ((FPRetType = PointeeTy->getAs<FunctionType>())) { ResultStr += FPRetType->getReturnType().getAsString(Context->getPrintingPolicy()); ResultStr += "(*"; } } else ResultStr += T.getAsString(Context->getPrintingPolicy()); } void RewriteObjC::RewriteObjCMethodDecl(const ObjCInterfaceDecl *IDecl, ObjCMethodDecl *OMD, std::string &ResultStr) { //fprintf(stderr,"In RewriteObjCMethodDecl\n"); const FunctionType *FPRetType = nullptr; ResultStr += "\nstatic "; RewriteTypeIntoString(OMD->getReturnType(), ResultStr, FPRetType); ResultStr += " "; // Unique method name std::string NameStr; if (OMD->isInstanceMethod()) NameStr += "_I_"; else NameStr += "_C_"; NameStr += IDecl->getNameAsString(); NameStr += "_"; if (ObjCCategoryImplDecl *CID = dyn_cast<ObjCCategoryImplDecl>(OMD->getDeclContext())) { NameStr += CID->getNameAsString(); NameStr += "_"; } // Append selector names, replacing ':' with '_' { std::string selString = OMD->getSelector().getAsString(); int len = selString.size(); for (int i = 0; i < len; i++) if (selString[i] == ':') selString[i] = '_'; NameStr += selString; } // Remember this name for metadata emission MethodInternalNames[OMD] = NameStr; ResultStr += NameStr; // Rewrite arguments ResultStr += "("; // invisible arguments if (OMD->isInstanceMethod()) { QualType selfTy = Context->getObjCInterfaceType(IDecl); selfTy = Context->getPointerType(selfTy); if (!LangOpts.MicrosoftExt) { if (ObjCSynthesizedStructs.count(const_cast<ObjCInterfaceDecl*>(IDecl))) ResultStr += "struct "; } // When rewriting for Microsoft, explicitly omit the structure name. ResultStr += IDecl->getNameAsString(); ResultStr += " *"; } else ResultStr += Context->getObjCClassType().getAsString( Context->getPrintingPolicy()); ResultStr += " self, "; ResultStr += Context->getObjCSelType().getAsString(Context->getPrintingPolicy()); ResultStr += " _cmd"; // Method arguments. for (const auto *PDecl : OMD->params()) { ResultStr += ", "; if (PDecl->getType()->isObjCQualifiedIdType()) { ResultStr += "id "; ResultStr += PDecl->getNameAsString(); } else { std::string Name = PDecl->getNameAsString(); QualType QT = PDecl->getType(); // Make sure we convert "t (^)(...)" to "t (*)(...)". (void)convertBlockPointerToFunctionPointer(QT); QT.getAsStringInternal(Name, Context->getPrintingPolicy()); ResultStr += Name; } } if (OMD->isVariadic()) ResultStr += ", ..."; ResultStr += ") "; if (FPRetType) { ResultStr += ")"; // close the precedence "scope" for "*". // Now, emit the argument types (if any). if (const FunctionProtoType *FT = dyn_cast<FunctionProtoType>(FPRetType)) { ResultStr += "("; for (unsigned i = 0, e = FT->getNumParams(); i != e; ++i) { if (i) ResultStr += ", "; std::string ParamStr = FT->getParamType(i).getAsString(Context->getPrintingPolicy()); ResultStr += ParamStr; } if (FT->isVariadic()) { if (FT->getNumParams()) ResultStr += ", "; ResultStr += "..."; } ResultStr += ")"; } else { ResultStr += "()"; } } } void RewriteObjC::RewriteImplementationDecl(Decl *OID) { ObjCImplementationDecl *IMD = dyn_cast<ObjCImplementationDecl>(OID); ObjCCategoryImplDecl *CID = dyn_cast<ObjCCategoryImplDecl>(OID); InsertText(IMD ? IMD->getLocStart() : CID->getLocStart(), "// "); for (auto *OMD : IMD ? IMD->instance_methods() : CID->instance_methods()) { std::string ResultStr; RewriteObjCMethodDecl(OMD->getClassInterface(), OMD, ResultStr); SourceLocation LocStart = OMD->getLocStart(); SourceLocation LocEnd = OMD->getCompoundBody()->getLocStart(); const char *startBuf = SM->getCharacterData(LocStart); const char *endBuf = SM->getCharacterData(LocEnd); ReplaceText(LocStart, endBuf-startBuf, ResultStr); } for (auto *OMD : IMD ? IMD->class_methods() : CID->class_methods()) { std::string ResultStr; RewriteObjCMethodDecl(OMD->getClassInterface(), OMD, ResultStr); SourceLocation LocStart = OMD->getLocStart(); SourceLocation LocEnd = OMD->getCompoundBody()->getLocStart(); const char *startBuf = SM->getCharacterData(LocStart); const char *endBuf = SM->getCharacterData(LocEnd); ReplaceText(LocStart, endBuf-startBuf, ResultStr); } for (auto *I : IMD ? IMD->property_impls() : CID->property_impls()) RewritePropertyImplDecl(I, IMD, CID); InsertText(IMD ? IMD->getLocEnd() : CID->getLocEnd(), "// "); } void RewriteObjC::RewriteInterfaceDecl(ObjCInterfaceDecl *ClassDecl) { std::string ResultStr; if (!ObjCForwardDecls.count(ClassDecl->getCanonicalDecl())) { // we haven't seen a forward decl - generate a typedef. ResultStr = "#ifndef _REWRITER_typedef_"; ResultStr += ClassDecl->getNameAsString(); ResultStr += "\n"; ResultStr += "#define _REWRITER_typedef_"; ResultStr += ClassDecl->getNameAsString(); ResultStr += "\n"; ResultStr += "typedef struct objc_object "; ResultStr += ClassDecl->getNameAsString(); ResultStr += ";\n#endif\n"; // Mark this typedef as having been generated. ObjCForwardDecls.insert(ClassDecl->getCanonicalDecl()); } RewriteObjCInternalStruct(ClassDecl, ResultStr); for (auto *I : ClassDecl->properties()) RewriteProperty(I); for (auto *I : ClassDecl->instance_methods()) RewriteMethodDeclaration(I); for (auto *I : ClassDecl->class_methods()) RewriteMethodDeclaration(I); // Lastly, comment out the @end. ReplaceText(ClassDecl->getAtEndRange().getBegin(), strlen("@end"), "/* @end */"); } Stmt *RewriteObjC::RewritePropertyOrImplicitSetter(PseudoObjectExpr *PseudoOp) { SourceRange OldRange = PseudoOp->getSourceRange(); // We just magically know some things about the structure of this // expression. ObjCMessageExpr *OldMsg = cast<ObjCMessageExpr>(PseudoOp->getSemanticExpr( PseudoOp->getNumSemanticExprs() - 1)); // Because the rewriter doesn't allow us to rewrite rewritten code, // we need to suppress rewriting the sub-statements. Expr *Base, *RHS; { DisableReplaceStmtScope S(*this); // Rebuild the base expression if we have one. Base = nullptr; if (OldMsg->getReceiverKind() == ObjCMessageExpr::Instance) { Base = OldMsg->getInstanceReceiver(); Base = cast<OpaqueValueExpr>(Base)->getSourceExpr(); Base = cast<Expr>(RewriteFunctionBodyOrGlobalInitializer(Base)); } // Rebuild the RHS. RHS = cast<BinaryOperator>(PseudoOp->getSyntacticForm())->getRHS(); RHS = cast<OpaqueValueExpr>(RHS)->getSourceExpr(); RHS = cast<Expr>(RewriteFunctionBodyOrGlobalInitializer(RHS)); } // TODO: avoid this copy. SmallVector<SourceLocation, 1> SelLocs; OldMsg->getSelectorLocs(SelLocs); ObjCMessageExpr *NewMsg = nullptr; switch (OldMsg->getReceiverKind()) { case ObjCMessageExpr::Class: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), OldMsg->getClassReceiverTypeInfo(), OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), RHS, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; case ObjCMessageExpr::Instance: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), Base, OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), RHS, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; case ObjCMessageExpr::SuperClass: case ObjCMessageExpr::SuperInstance: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), OldMsg->getSuperLoc(), OldMsg->getReceiverKind() == ObjCMessageExpr::SuperInstance, OldMsg->getSuperType(), OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), RHS, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; } Stmt *Replacement = SynthMessageExpr(NewMsg); ReplaceStmtWithRange(PseudoOp, Replacement, OldRange); return Replacement; } Stmt *RewriteObjC::RewritePropertyOrImplicitGetter(PseudoObjectExpr *PseudoOp) { SourceRange OldRange = PseudoOp->getSourceRange(); // We just magically know some things about the structure of this // expression. ObjCMessageExpr *OldMsg = cast<ObjCMessageExpr>(PseudoOp->getResultExpr()->IgnoreImplicit()); // Because the rewriter doesn't allow us to rewrite rewritten code, // we need to suppress rewriting the sub-statements. Expr *Base = nullptr; { DisableReplaceStmtScope S(*this); // Rebuild the base expression if we have one. if (OldMsg->getReceiverKind() == ObjCMessageExpr::Instance) { Base = OldMsg->getInstanceReceiver(); Base = cast<OpaqueValueExpr>(Base)->getSourceExpr(); Base = cast<Expr>(RewriteFunctionBodyOrGlobalInitializer(Base)); } } // Intentionally empty. SmallVector<SourceLocation, 1> SelLocs; SmallVector<Expr*, 1> Args; ObjCMessageExpr *NewMsg = nullptr; switch (OldMsg->getReceiverKind()) { case ObjCMessageExpr::Class: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), OldMsg->getClassReceiverTypeInfo(), OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), Args, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; case ObjCMessageExpr::Instance: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), Base, OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), Args, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; case ObjCMessageExpr::SuperClass: case ObjCMessageExpr::SuperInstance: NewMsg = ObjCMessageExpr::Create(*Context, OldMsg->getType(), OldMsg->getValueKind(), OldMsg->getLeftLoc(), OldMsg->getSuperLoc(), OldMsg->getReceiverKind() == ObjCMessageExpr::SuperInstance, OldMsg->getSuperType(), OldMsg->getSelector(), SelLocs, OldMsg->getMethodDecl(), Args, OldMsg->getRightLoc(), OldMsg->isImplicit()); break; } Stmt *Replacement = SynthMessageExpr(NewMsg); ReplaceStmtWithRange(PseudoOp, Replacement, OldRange); return Replacement; } /// SynthCountByEnumWithState - To print: /// ((unsigned int (*) /// (id, SEL, struct __objcFastEnumerationState *, id *, unsigned int)) /// (void *)objc_msgSend)((id)l_collection, /// sel_registerName( /// "countByEnumeratingWithState:objects:count:"), /// &enumState, /// (id *)__rw_items, (unsigned int)16) /// void RewriteObjC::SynthCountByEnumWithState(std::string &buf) { buf += "((unsigned int (*) (id, SEL, struct __objcFastEnumerationState *, " "id *, unsigned int))(void *)objc_msgSend)"; buf += "\n\t\t"; buf += "((id)l_collection,\n\t\t"; buf += "sel_registerName(\"countByEnumeratingWithState:objects:count:\"),"; buf += "\n\t\t"; buf += "&enumState, " "(id *)__rw_items, (unsigned int)16)"; } /// RewriteBreakStmt - Rewrite for a break-stmt inside an ObjC2's foreach /// statement to exit to its outer synthesized loop. /// Stmt *RewriteObjC::RewriteBreakStmt(BreakStmt *S) { if (Stmts.empty() || !isa<ObjCForCollectionStmt>(Stmts.back())) return S; // replace break with goto __break_label std::string buf; SourceLocation startLoc = S->getLocStart(); buf = "goto __break_label_"; buf += utostr(ObjCBcLabelNo.back()); ReplaceText(startLoc, strlen("break"), buf); return nullptr; } /// RewriteContinueStmt - Rewrite for a continue-stmt inside an ObjC2's foreach /// statement to continue with its inner synthesized loop. /// Stmt *RewriteObjC::RewriteContinueStmt(ContinueStmt *S) { if (Stmts.empty() || !isa<ObjCForCollectionStmt>(Stmts.back())) return S; // replace continue with goto __continue_label std::string buf; SourceLocation startLoc = S->getLocStart(); buf = "goto __continue_label_"; buf += utostr(ObjCBcLabelNo.back()); ReplaceText(startLoc, strlen("continue"), buf); return nullptr; } /// RewriteObjCForCollectionStmt - Rewriter for ObjC2's foreach statement. /// It rewrites: /// for ( type elem in collection) { stmts; } /// Into: /// { /// type elem; /// struct __objcFastEnumerationState enumState = { 0 }; /// id __rw_items[16]; /// id l_collection = (id)collection; /// unsigned long limit = [l_collection countByEnumeratingWithState:&enumState /// objects:__rw_items count:16]; /// if (limit) { /// unsigned long startMutations = *enumState.mutationsPtr; /// do { /// unsigned long counter = 0; /// do { /// if (startMutations != *enumState.mutationsPtr) /// objc_enumerationMutation(l_collection); /// elem = (type)enumState.itemsPtr[counter++]; /// stmts; /// __continue_label: ; /// } while (counter < limit); /// } while (limit = [l_collection countByEnumeratingWithState:&enumState /// objects:__rw_items count:16]); /// elem = nil; /// __break_label: ; /// } /// else /// elem = nil; /// } /// Stmt *RewriteObjC::RewriteObjCForCollectionStmt(ObjCForCollectionStmt *S, SourceLocation OrigEnd) { assert(!Stmts.empty() && "ObjCForCollectionStmt - Statement stack empty"); assert(isa<ObjCForCollectionStmt>(Stmts.back()) && "ObjCForCollectionStmt Statement stack mismatch"); assert(!ObjCBcLabelNo.empty() && "ObjCForCollectionStmt - Label No stack empty"); SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); StringRef elementName; std::string elementTypeAsString; std::string buf; buf = "\n{\n\t"; if (DeclStmt *DS = dyn_cast<DeclStmt>(S->getElement())) { // type elem; NamedDecl* D = cast<NamedDecl>(DS->getSingleDecl()); QualType ElementType = cast<ValueDecl>(D)->getType(); if (ElementType->isObjCQualifiedIdType() || ElementType->isObjCQualifiedInterfaceType()) // Simply use 'id' for all qualified types. elementTypeAsString = "id"; else elementTypeAsString = ElementType.getAsString(Context->getPrintingPolicy()); buf += elementTypeAsString; buf += " "; elementName = D->getName(); buf += elementName; buf += ";\n\t"; } else { DeclRefExpr *DR = cast<DeclRefExpr>(S->getElement()); elementName = DR->getDecl()->getName(); ValueDecl *VD = cast<ValueDecl>(DR->getDecl()); if (VD->getType()->isObjCQualifiedIdType() || VD->getType()->isObjCQualifiedInterfaceType()) // Simply use 'id' for all qualified types. elementTypeAsString = "id"; else elementTypeAsString = VD->getType().getAsString(Context->getPrintingPolicy()); } // struct __objcFastEnumerationState enumState = { 0 }; buf += "struct __objcFastEnumerationState enumState = { 0 };\n\t"; // id __rw_items[16]; buf += "id __rw_items[16];\n\t"; // id l_collection = (id) buf += "id l_collection = (id)"; // Find start location of 'collection' the hard way! const char *startCollectionBuf = startBuf; startCollectionBuf += 3; // skip 'for' startCollectionBuf = strchr(startCollectionBuf, '('); startCollectionBuf++; // skip '(' // find 'in' and skip it. while (*startCollectionBuf != ' ' || *(startCollectionBuf+1) != 'i' || *(startCollectionBuf+2) != 'n' || (*(startCollectionBuf+3) != ' ' && *(startCollectionBuf+3) != '[' && *(startCollectionBuf+3) != '(')) startCollectionBuf++; startCollectionBuf += 3; // Replace: "for (type element in" with string constructed thus far. ReplaceText(startLoc, startCollectionBuf - startBuf, buf); // Replace ')' in for '(' type elem in collection ')' with ';' SourceLocation rightParenLoc = S->getRParenLoc(); const char *rparenBuf = SM->getCharacterData(rightParenLoc); SourceLocation lparenLoc = startLoc.getLocWithOffset(rparenBuf-startBuf); buf = ";\n\t"; // unsigned long limit = [l_collection countByEnumeratingWithState:&enumState // objects:__rw_items count:16]; // which is synthesized into: // unsigned int limit = // ((unsigned int (*) // (id, SEL, struct __objcFastEnumerationState *, id *, unsigned int)) // (void *)objc_msgSend)((id)l_collection, // sel_registerName( // "countByEnumeratingWithState:objects:count:"), // (struct __objcFastEnumerationState *)&state, // (id *)__rw_items, (unsigned int)16); buf += "unsigned long limit =\n\t\t"; SynthCountByEnumWithState(buf); buf += ";\n\t"; /// if (limit) { /// unsigned long startMutations = *enumState.mutationsPtr; /// do { /// unsigned long counter = 0; /// do { /// if (startMutations != *enumState.mutationsPtr) /// objc_enumerationMutation(l_collection); /// elem = (type)enumState.itemsPtr[counter++]; buf += "if (limit) {\n\t"; buf += "unsigned long startMutations = *enumState.mutationsPtr;\n\t"; buf += "do {\n\t\t"; buf += "unsigned long counter = 0;\n\t\t"; buf += "do {\n\t\t\t"; buf += "if (startMutations != *enumState.mutationsPtr)\n\t\t\t\t"; buf += "objc_enumerationMutation(l_collection);\n\t\t\t"; buf += elementName; buf += " = ("; buf += elementTypeAsString; buf += ")enumState.itemsPtr[counter++];"; // Replace ')' in for '(' type elem in collection ')' with all of these. ReplaceText(lparenLoc, 1, buf); /// __continue_label: ; /// } while (counter < limit); /// } while (limit = [l_collection countByEnumeratingWithState:&enumState /// objects:__rw_items count:16]); /// elem = nil; /// __break_label: ; /// } /// else /// elem = nil; /// } /// buf = ";\n\t"; buf += "__continue_label_"; buf += utostr(ObjCBcLabelNo.back()); buf += ": ;"; buf += "\n\t\t"; buf += "} while (counter < limit);\n\t"; buf += "} while (limit = "; SynthCountByEnumWithState(buf); buf += ");\n\t"; buf += elementName; buf += " = (("; buf += elementTypeAsString; buf += ")0);\n\t"; buf += "__break_label_"; buf += utostr(ObjCBcLabelNo.back()); buf += ": ;\n\t"; buf += "}\n\t"; buf += "else\n\t\t"; buf += elementName; buf += " = (("; buf += elementTypeAsString; buf += ")0);\n\t"; buf += "}\n"; // Insert all these *after* the statement body. // FIXME: If this should support Obj-C++, support CXXTryStmt if (isa<CompoundStmt>(S->getBody())) { SourceLocation endBodyLoc = OrigEnd.getLocWithOffset(1); InsertText(endBodyLoc, buf); } else { /* Need to treat single statements specially. For example: * * for (A *a in b) if (stuff()) break; * for (A *a in b) xxxyy; * * The following code simply scans ahead to the semi to find the actual end. */ const char *stmtBuf = SM->getCharacterData(OrigEnd); const char *semiBuf = strchr(stmtBuf, ';'); assert(semiBuf && "Can't find ';'"); SourceLocation endBodyLoc = OrigEnd.getLocWithOffset(semiBuf-stmtBuf+1); InsertText(endBodyLoc, buf); } Stmts.pop_back(); ObjCBcLabelNo.pop_back(); return nullptr; } /// RewriteObjCSynchronizedStmt - /// This routine rewrites @synchronized(expr) stmt; /// into: /// objc_sync_enter(expr); /// @try stmt @finally { objc_sync_exit(expr); } /// Stmt *RewriteObjC::RewriteObjCSynchronizedStmt(ObjCAtSynchronizedStmt *S) { // Get the start location and compute the semi location. SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @synchronized location"); std::string buf; buf = "objc_sync_enter((id)"; const char *lparenBuf = startBuf; while (*lparenBuf != '(') lparenBuf++; ReplaceText(startLoc, lparenBuf-startBuf+1, buf); // We can't use S->getSynchExpr()->getLocEnd() to find the end location, since // the sync expression is typically a message expression that's already // been rewritten! (which implies the SourceLocation's are invalid). SourceLocation endLoc = S->getSynchBody()->getLocStart(); const char *endBuf = SM->getCharacterData(endLoc); while (*endBuf != ')') endBuf--; SourceLocation rparenLoc = startLoc.getLocWithOffset(endBuf-startBuf); buf = ");\n"; // declare a new scope with two variables, _stack and _rethrow. buf += "/* @try scope begin */ \n{ struct _objc_exception_data {\n"; buf += "int buf[18/*32-bit i386*/];\n"; buf += "char *pointers[4];} _stack;\n"; buf += "id volatile _rethrow = 0;\n"; buf += "objc_exception_try_enter(&_stack);\n"; buf += "if (!_setjmp(_stack.buf)) /* @try block continue */\n"; ReplaceText(rparenLoc, 1, buf); startLoc = S->getSynchBody()->getLocEnd(); startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '}') && "bogus @synchronized block"); SourceLocation lastCurlyLoc = startLoc; buf = "}\nelse {\n"; buf += " _rethrow = objc_exception_extract(&_stack);\n"; buf += "}\n"; buf += "{ /* implicit finally clause */\n"; buf += " if (!_rethrow) objc_exception_try_exit(&_stack);\n"; std::string syncBuf; syncBuf += " objc_sync_exit("; Expr *syncExpr = S->getSynchExpr(); CastKind CK = syncExpr->getType()->isObjCObjectPointerType() ? CK_BitCast : syncExpr->getType()->isBlockPointerType() ? CK_BlockPointerToObjCPointerCast : CK_CPointerToObjCPointerCast; syncExpr = NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK, syncExpr); std::string syncExprBufS; llvm::raw_string_ostream syncExprBuf(syncExprBufS); assert(syncExpr != nullptr && "Expected non-null Expr"); syncExpr->printPretty(syncExprBuf, nullptr, PrintingPolicy(LangOpts)); syncBuf += syncExprBuf.str(); syncBuf += ");"; buf += syncBuf; buf += "\n if (_rethrow) objc_exception_throw(_rethrow);\n"; buf += "}\n"; buf += "}"; ReplaceText(lastCurlyLoc, 1, buf); bool hasReturns = false; HasReturnStmts(S->getSynchBody(), hasReturns); if (hasReturns) RewriteSyncReturnStmts(S->getSynchBody(), syncBuf); return nullptr; } void RewriteObjC::WarnAboutReturnGotoStmts(Stmt *S) { // Perform a bottom up traversal of all children. for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) WarnAboutReturnGotoStmts(*CI); if (isa<ReturnStmt>(S) || isa<GotoStmt>(S)) { Diags.Report(Context->getFullLoc(S->getLocStart()), TryFinallyContainsReturnDiag); } return; } void RewriteObjC::HasReturnStmts(Stmt *S, bool &hasReturns) { // Perform a bottom up traversal of all children. for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) HasReturnStmts(*CI, hasReturns); if (isa<ReturnStmt>(S)) hasReturns = true; return; } void RewriteObjC::RewriteTryReturnStmts(Stmt *S) { // Perform a bottom up traversal of all children. for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) { RewriteTryReturnStmts(*CI); } if (isa<ReturnStmt>(S)) { SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); const char *semiBuf = strchr(startBuf, ';'); assert((*semiBuf == ';') && "RewriteTryReturnStmts: can't find ';'"); SourceLocation onePastSemiLoc = startLoc.getLocWithOffset(semiBuf-startBuf+1); std::string buf; buf = "{ objc_exception_try_exit(&_stack); return"; ReplaceText(startLoc, 6, buf); InsertText(onePastSemiLoc, "}"); } return; } void RewriteObjC::RewriteSyncReturnStmts(Stmt *S, std::string syncExitBuf) { // Perform a bottom up traversal of all children. for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) { RewriteSyncReturnStmts(*CI, syncExitBuf); } if (isa<ReturnStmt>(S)) { SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); const char *semiBuf = strchr(startBuf, ';'); assert((*semiBuf == ';') && "RewriteSyncReturnStmts: can't find ';'"); SourceLocation onePastSemiLoc = startLoc.getLocWithOffset(semiBuf-startBuf+1); std::string buf; buf = "{ objc_exception_try_exit(&_stack);"; buf += syncExitBuf; buf += " return"; ReplaceText(startLoc, 6, buf); InsertText(onePastSemiLoc, "}"); } return; } Stmt *RewriteObjC::RewriteObjCTryStmt(ObjCAtTryStmt *S) { // Get the start location and compute the semi location. SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @try location"); std::string buf; // declare a new scope with two variables, _stack and _rethrow. buf = "/* @try scope begin */ { struct _objc_exception_data {\n"; buf += "int buf[18/*32-bit i386*/];\n"; buf += "char *pointers[4];} _stack;\n"; buf += "id volatile _rethrow = 0;\n"; buf += "objc_exception_try_enter(&_stack);\n"; buf += "if (!_setjmp(_stack.buf)) /* @try block continue */\n"; ReplaceText(startLoc, 4, buf); startLoc = S->getTryBody()->getLocEnd(); startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '}') && "bogus @try block"); SourceLocation lastCurlyLoc = startLoc; if (S->getNumCatchStmts()) { startLoc = startLoc.getLocWithOffset(1); buf = " /* @catch begin */ else {\n"; buf += " id _caught = objc_exception_extract(&_stack);\n"; buf += " objc_exception_try_enter (&_stack);\n"; buf += " if (_setjmp(_stack.buf))\n"; buf += " _rethrow = objc_exception_extract(&_stack);\n"; buf += " else { /* @catch continue */"; InsertText(startLoc, buf); } else { /* no catch list */ buf = "}\nelse {\n"; buf += " _rethrow = objc_exception_extract(&_stack);\n"; buf += "}"; ReplaceText(lastCurlyLoc, 1, buf); } Stmt *lastCatchBody = nullptr; for (unsigned I = 0, N = S->getNumCatchStmts(); I != N; ++I) { ObjCAtCatchStmt *Catch = S->getCatchStmt(I); VarDecl *catchDecl = Catch->getCatchParamDecl(); if (I == 0) buf = "if ("; // we are generating code for the first catch clause else buf = "else if ("; startLoc = Catch->getLocStart(); startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @catch location"); const char *lParenLoc = strchr(startBuf, '('); if (Catch->hasEllipsis()) { // Now rewrite the body... lastCatchBody = Catch->getCatchBody(); SourceLocation bodyLoc = lastCatchBody->getLocStart(); const char *bodyBuf = SM->getCharacterData(bodyLoc); assert(*SM->getCharacterData(Catch->getRParenLoc()) == ')' && "bogus @catch paren location"); assert((*bodyBuf == '{') && "bogus @catch body location"); buf += "1) { id _tmp = _caught;"; Rewrite.ReplaceText(startLoc, bodyBuf-startBuf+1, buf); } else if (catchDecl) { QualType t = catchDecl->getType(); if (t == Context->getObjCIdType()) { buf += "1) { "; ReplaceText(startLoc, lParenLoc-startBuf+1, buf); } else if (const ObjCObjectPointerType *Ptr = t->getAs<ObjCObjectPointerType>()) { // Should be a pointer to a class. ObjCInterfaceDecl *IDecl = Ptr->getObjectType()->getInterface(); if (IDecl) { buf += "objc_exception_match((struct objc_class *)objc_getClass(\""; buf += IDecl->getNameAsString(); buf += "\"), (struct objc_object *)_caught)) { "; ReplaceText(startLoc, lParenLoc-startBuf+1, buf); } } // Now rewrite the body... lastCatchBody = Catch->getCatchBody(); SourceLocation rParenLoc = Catch->getRParenLoc(); SourceLocation bodyLoc = lastCatchBody->getLocStart(); const char *bodyBuf = SM->getCharacterData(bodyLoc); const char *rParenBuf = SM->getCharacterData(rParenLoc); assert((*rParenBuf == ')') && "bogus @catch paren location"); assert((*bodyBuf == '{') && "bogus @catch body location"); // Here we replace ") {" with "= _caught;" (which initializes and // declares the @catch parameter). ReplaceText(rParenLoc, bodyBuf-rParenBuf+1, " = _caught;"); } else { llvm_unreachable("@catch rewrite bug"); } } // Complete the catch list... if (lastCatchBody) { SourceLocation bodyLoc = lastCatchBody->getLocEnd(); assert(*SM->getCharacterData(bodyLoc) == '}' && "bogus @catch body location"); // Insert the last (implicit) else clause *before* the right curly brace. bodyLoc = bodyLoc.getLocWithOffset(-1); buf = "} /* last catch end */\n"; buf += "else {\n"; buf += " _rethrow = _caught;\n"; buf += " objc_exception_try_exit(&_stack);\n"; buf += "} } /* @catch end */\n"; if (!S->getFinallyStmt()) buf += "}\n"; InsertText(bodyLoc, buf); // Set lastCurlyLoc lastCurlyLoc = lastCatchBody->getLocEnd(); } if (ObjCAtFinallyStmt *finalStmt = S->getFinallyStmt()) { startLoc = finalStmt->getLocStart(); startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @finally start"); ReplaceText(startLoc, 8, "/* @finally */"); Stmt *body = finalStmt->getFinallyBody(); SourceLocation startLoc = body->getLocStart(); SourceLocation endLoc = body->getLocEnd(); assert(*SM->getCharacterData(startLoc) == '{' && "bogus @finally body location"); assert(*SM->getCharacterData(endLoc) == '}' && "bogus @finally body location"); startLoc = startLoc.getLocWithOffset(1); InsertText(startLoc, " if (!_rethrow) objc_exception_try_exit(&_stack);\n"); endLoc = endLoc.getLocWithOffset(-1); InsertText(endLoc, " if (_rethrow) objc_exception_throw(_rethrow);\n"); // Set lastCurlyLoc lastCurlyLoc = body->getLocEnd(); // Now check for any return/continue/go statements within the @try. WarnAboutReturnGotoStmts(S->getTryBody()); } else { /* no finally clause - make sure we synthesize an implicit one */ buf = "{ /* implicit finally clause */\n"; buf += " if (!_rethrow) objc_exception_try_exit(&_stack);\n"; buf += " if (_rethrow) objc_exception_throw(_rethrow);\n"; buf += "}"; ReplaceText(lastCurlyLoc, 1, buf); // Now check for any return/continue/go statements within the @try. // The implicit finally clause won't called if the @try contains any // jump statements. bool hasReturns = false; HasReturnStmts(S->getTryBody(), hasReturns); if (hasReturns) RewriteTryReturnStmts(S->getTryBody()); } // Now emit the final closing curly brace... lastCurlyLoc = lastCurlyLoc.getLocWithOffset(1); InsertText(lastCurlyLoc, " } /* @try scope end */\n"); return nullptr; } // This can't be done with ReplaceStmt(S, ThrowExpr), since // the throw expression is typically a message expression that's already // been rewritten! (which implies the SourceLocation's are invalid). Stmt *RewriteObjC::RewriteObjCThrowStmt(ObjCAtThrowStmt *S) { // Get the start location and compute the semi location. SourceLocation startLoc = S->getLocStart(); const char *startBuf = SM->getCharacterData(startLoc); assert((*startBuf == '@') && "bogus @throw location"); std::string buf; /* void objc_exception_throw(id) __attribute__((noreturn)); */ if (S->getThrowExpr()) buf = "objc_exception_throw("; else // add an implicit argument buf = "objc_exception_throw(_caught"; // handle "@ throw" correctly. const char *wBuf = strchr(startBuf, 'w'); assert((*wBuf == 'w') && "@throw: can't find 'w'"); ReplaceText(startLoc, wBuf-startBuf+1, buf); const char *semiBuf = strchr(startBuf, ';'); assert((*semiBuf == ';') && "@throw: can't find ';'"); SourceLocation semiLoc = startLoc.getLocWithOffset(semiBuf-startBuf); ReplaceText(semiLoc, 1, ");"); return nullptr; } Stmt *RewriteObjC::RewriteAtEncode(ObjCEncodeExpr *Exp) { // Create a new string expression. std::string StrEncoding; Context->getObjCEncodingForType(Exp->getEncodedType(), StrEncoding); Expr *Replacement = getStringLiteral(StrEncoding); ReplaceStmt(Exp, Replacement); // Replace this subexpr in the parent. // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return Replacement; } Stmt *RewriteObjC::RewriteAtSelector(ObjCSelectorExpr *Exp) { if (!SelGetUidFunctionDecl) SynthSelGetUidFunctionDecl(); assert(SelGetUidFunctionDecl && "Can't find sel_registerName() decl"); // Create a call to sel_registerName("selName"). SmallVector<Expr*, 8> SelExprs; SelExprs.push_back(getStringLiteral(Exp->getSelector().getAsString())); CallExpr *SelExp = SynthesizeCallToFunctionDecl(SelGetUidFunctionDecl, &SelExprs[0], SelExprs.size()); ReplaceStmt(Exp, SelExp); // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return SelExp; } CallExpr *RewriteObjC::SynthesizeCallToFunctionDecl( FunctionDecl *FD, Expr **args, unsigned nargs, SourceLocation StartLoc, SourceLocation EndLoc) { // Get the type, we will need to reference it in a couple spots. QualType msgSendType = FD->getType(); // Create a reference to the objc_msgSend() declaration. DeclRefExpr *DRE = new (Context) DeclRefExpr(FD, false, msgSendType, VK_LValue, SourceLocation()); // Now, we cast the reference to a pointer to the objc_msgSend type. QualType pToFunc = Context->getPointerType(msgSendType); ImplicitCastExpr *ICE = ImplicitCastExpr::Create(*Context, pToFunc, CK_FunctionToPointerDecay, DRE, nullptr, VK_RValue); const FunctionType *FT = msgSendType->getAs<FunctionType>(); CallExpr *Exp = new (Context) CallExpr(*Context, ICE, llvm::makeArrayRef(args, nargs), FT->getCallResultType(*Context), VK_RValue, EndLoc); return Exp; } static bool scanForProtocolRefs(const char *startBuf, const char *endBuf, const char *&startRef, const char *&endRef) { while (startBuf < endBuf) { if (*startBuf == '<') startRef = startBuf; // mark the start. if (*startBuf == '>') { if (startRef && *startRef == '<') { endRef = startBuf; // mark the end. return true; } return false; } startBuf++; } return false; } static void scanToNextArgument(const char *&argRef) { int angle = 0; while (*argRef != ')' && (*argRef != ',' || angle > 0)) { if (*argRef == '<') angle++; else if (*argRef == '>') angle--; argRef++; } assert(angle == 0 && "scanToNextArgument - bad protocol type syntax"); } bool RewriteObjC::needToScanForQualifiers(QualType T) { if (T->isObjCQualifiedIdType()) return true; if (const PointerType *PT = T->getAs<PointerType>()) { if (PT->getPointeeType()->isObjCQualifiedIdType()) return true; } if (T->isObjCObjectPointerType()) { T = T->getPointeeType(); return T->isObjCQualifiedInterfaceType(); } if (T->isArrayType()) { QualType ElemTy = Context->getBaseElementType(T); return needToScanForQualifiers(ElemTy); } return false; } void RewriteObjC::RewriteObjCQualifiedInterfaceTypes(Expr *E) { QualType Type = E->getType(); if (needToScanForQualifiers(Type)) { SourceLocation Loc, EndLoc; if (const CStyleCastExpr *ECE = dyn_cast<CStyleCastExpr>(E)) { Loc = ECE->getLParenLoc(); EndLoc = ECE->getRParenLoc(); } else { Loc = E->getLocStart(); EndLoc = E->getLocEnd(); } // This will defend against trying to rewrite synthesized expressions. if (Loc.isInvalid() || EndLoc.isInvalid()) return; const char *startBuf = SM->getCharacterData(Loc); const char *endBuf = SM->getCharacterData(EndLoc); const char *startRef = nullptr, *endRef = nullptr; if (scanForProtocolRefs(startBuf, endBuf, startRef, endRef)) { // Get the locations of the startRef, endRef. SourceLocation LessLoc = Loc.getLocWithOffset(startRef-startBuf); SourceLocation GreaterLoc = Loc.getLocWithOffset(endRef-startBuf+1); // Comment out the protocol references. InsertText(LessLoc, "/*"); InsertText(GreaterLoc, "*/"); } } } void RewriteObjC::RewriteObjCQualifiedInterfaceTypes(Decl *Dcl) { SourceLocation Loc; QualType Type; const FunctionProtoType *proto = nullptr; if (VarDecl *VD = dyn_cast<VarDecl>(Dcl)) { Loc = VD->getLocation(); Type = VD->getType(); } else if (FunctionDecl *FD = dyn_cast<FunctionDecl>(Dcl)) { Loc = FD->getLocation(); // Check for ObjC 'id' and class types that have been adorned with protocol // information (id<p>, C<p>*). The protocol references need to be rewritten! const FunctionType *funcType = FD->getType()->getAs<FunctionType>(); assert(funcType && "missing function type"); proto = dyn_cast<FunctionProtoType>(funcType); if (!proto) return; Type = proto->getReturnType(); } else if (FieldDecl *FD = dyn_cast<FieldDecl>(Dcl)) { Loc = FD->getLocation(); Type = FD->getType(); } else return; if (needToScanForQualifiers(Type)) { // Since types are unique, we need to scan the buffer. const char *endBuf = SM->getCharacterData(Loc); const char *startBuf = endBuf; while (*startBuf != ';' && *startBuf != '<' && startBuf != MainFileStart) startBuf--; // scan backward (from the decl location) for return type. const char *startRef = nullptr, *endRef = nullptr; if (scanForProtocolRefs(startBuf, endBuf, startRef, endRef)) { // Get the locations of the startRef, endRef. SourceLocation LessLoc = Loc.getLocWithOffset(startRef-endBuf); SourceLocation GreaterLoc = Loc.getLocWithOffset(endRef-endBuf+1); // Comment out the protocol references. InsertText(LessLoc, "/*"); InsertText(GreaterLoc, "*/"); } } if (!proto) return; // most likely, was a variable // Now check arguments. const char *startBuf = SM->getCharacterData(Loc); const char *startFuncBuf = startBuf; for (unsigned i = 0; i < proto->getNumParams(); i++) { if (needToScanForQualifiers(proto->getParamType(i))) { // Since types are unique, we need to scan the buffer. const char *endBuf = startBuf; // scan forward (from the decl location) for argument types. scanToNextArgument(endBuf); const char *startRef = nullptr, *endRef = nullptr; if (scanForProtocolRefs(startBuf, endBuf, startRef, endRef)) { // Get the locations of the startRef, endRef. SourceLocation LessLoc = Loc.getLocWithOffset(startRef-startFuncBuf); SourceLocation GreaterLoc = Loc.getLocWithOffset(endRef-startFuncBuf+1); // Comment out the protocol references. InsertText(LessLoc, "/*"); InsertText(GreaterLoc, "*/"); } startBuf = ++endBuf; } else { // If the function name is derived from a macro expansion, then the // argument buffer will not follow the name. Need to speak with Chris. while (*startBuf && *startBuf != ')' && *startBuf != ',') startBuf++; // scan forward (from the decl location) for argument types. startBuf++; } } } void RewriteObjC::RewriteTypeOfDecl(VarDecl *ND) { QualType QT = ND->getType(); const Type* TypePtr = QT->getAs<Type>(); if (!isa<TypeOfExprType>(TypePtr)) return; while (isa<TypeOfExprType>(TypePtr)) { const TypeOfExprType *TypeOfExprTypePtr = cast<TypeOfExprType>(TypePtr); QT = TypeOfExprTypePtr->getUnderlyingExpr()->getType(); TypePtr = QT->getAs<Type>(); } // FIXME. This will not work for multiple declarators; as in: // __typeof__(a) b,c,d; std::string TypeAsString(QT.getAsString(Context->getPrintingPolicy())); SourceLocation DeclLoc = ND->getTypeSpecStartLoc(); const char *startBuf = SM->getCharacterData(DeclLoc); if (ND->getInit()) { std::string Name(ND->getNameAsString()); TypeAsString += " " + Name + " = "; Expr *E = ND->getInit(); SourceLocation startLoc; if (const CStyleCastExpr *ECE = dyn_cast<CStyleCastExpr>(E)) startLoc = ECE->getLParenLoc(); else startLoc = E->getLocStart(); startLoc = SM->getExpansionLoc(startLoc); const char *endBuf = SM->getCharacterData(startLoc); ReplaceText(DeclLoc, endBuf-startBuf-1, TypeAsString); } else { SourceLocation X = ND->getLocEnd(); X = SM->getExpansionLoc(X); const char *endBuf = SM->getCharacterData(X); ReplaceText(DeclLoc, endBuf-startBuf-1, TypeAsString); } } // SynthSelGetUidFunctionDecl - SEL sel_registerName(const char *str); void RewriteObjC::SynthSelGetUidFunctionDecl() { IdentifierInfo *SelGetUidIdent = &Context->Idents.get("sel_registerName"); SmallVector<QualType, 16> ArgTys; ArgTys.push_back(Context->getPointerType(Context->CharTy.withConst())); QualType getFuncType = getSimpleFunctionType(Context->getObjCSelType(), ArgTys); SelGetUidFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), SelGetUidIdent, getFuncType, nullptr, SC_Extern); } void RewriteObjC::RewriteFunctionDecl(FunctionDecl *FD) { // declared in <objc/objc.h> if (FD->getIdentifier() && FD->getName() == "sel_registerName") { SelGetUidFunctionDecl = FD; return; } RewriteObjCQualifiedInterfaceTypes(FD); } void RewriteObjC::RewriteBlockPointerType(std::string& Str, QualType Type) { std::string TypeString(Type.getAsString(Context->getPrintingPolicy())); const char *argPtr = TypeString.c_str(); if (!strchr(argPtr, '^')) { Str += TypeString; return; } while (*argPtr) { Str += (*argPtr == '^' ? '*' : *argPtr); argPtr++; } } // FIXME. Consolidate this routine with RewriteBlockPointerType. void RewriteObjC::RewriteBlockPointerTypeVariable(std::string& Str, ValueDecl *VD) { QualType Type = VD->getType(); std::string TypeString(Type.getAsString(Context->getPrintingPolicy())); const char *argPtr = TypeString.c_str(); int paren = 0; while (*argPtr) { switch (*argPtr) { case '(': Str += *argPtr; paren++; break; case ')': Str += *argPtr; paren--; break; case '^': Str += '*'; if (paren == 1) Str += VD->getNameAsString(); break; default: Str += *argPtr; break; } argPtr++; } } void RewriteObjC::RewriteBlockLiteralFunctionDecl(FunctionDecl *FD) { SourceLocation FunLocStart = FD->getTypeSpecStartLoc(); const FunctionType *funcType = FD->getType()->getAs<FunctionType>(); const FunctionProtoType *proto = dyn_cast<FunctionProtoType>(funcType); if (!proto) return; QualType Type = proto->getReturnType(); std::string FdStr = Type.getAsString(Context->getPrintingPolicy()); FdStr += " "; FdStr += FD->getName(); FdStr += "("; unsigned numArgs = proto->getNumParams(); for (unsigned i = 0; i < numArgs; i++) { QualType ArgType = proto->getParamType(i); RewriteBlockPointerType(FdStr, ArgType); if (i+1 < numArgs) FdStr += ", "; } FdStr += ");\n"; InsertText(FunLocStart, FdStr); CurFunctionDeclToDeclareForBlock = nullptr; } // SynthSuperConstructorFunctionDecl - id objc_super(id obj, id super); void RewriteObjC::SynthSuperConstructorFunctionDecl() { if (SuperConstructorFunctionDecl) return; IdentifierInfo *msgSendIdent = &Context->Idents.get("__rw_objc_super"); SmallVector<QualType, 16> ArgTys; QualType argT = Context->getObjCIdType(); assert(!argT.isNull() && "Can't find 'id' type"); ArgTys.push_back(argT); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys); SuperConstructorFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthMsgSendFunctionDecl - id objc_msgSend(id self, SEL op, ...); void RewriteObjC::SynthMsgSendFunctionDecl() { IdentifierInfo *msgSendIdent = &Context->Idents.get("objc_msgSend"); SmallVector<QualType, 16> ArgTys; QualType argT = Context->getObjCIdType(); assert(!argT.isNull() && "Can't find 'id' type"); ArgTys.push_back(argT); argT = Context->getObjCSelType(); assert(!argT.isNull() && "Can't find 'SEL' type"); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys, /*isVariadic=*/true); MsgSendFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthMsgSendSuperFunctionDecl - id objc_msgSendSuper(struct objc_super *, SEL op, ...); void RewriteObjC::SynthMsgSendSuperFunctionDecl() { IdentifierInfo *msgSendIdent = &Context->Idents.get("objc_msgSendSuper"); SmallVector<QualType, 16> ArgTys; RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("objc_super")); QualType argT = Context->getPointerType(Context->getTagDeclType(RD)); assert(!argT.isNull() && "Can't build 'struct objc_super *' type"); ArgTys.push_back(argT); argT = Context->getObjCSelType(); assert(!argT.isNull() && "Can't find 'SEL' type"); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys, /*isVariadic=*/true); MsgSendSuperFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthMsgSendStretFunctionDecl - id objc_msgSend_stret(id self, SEL op, ...); void RewriteObjC::SynthMsgSendStretFunctionDecl() { IdentifierInfo *msgSendIdent = &Context->Idents.get("objc_msgSend_stret"); SmallVector<QualType, 16> ArgTys; QualType argT = Context->getObjCIdType(); assert(!argT.isNull() && "Can't find 'id' type"); ArgTys.push_back(argT); argT = Context->getObjCSelType(); assert(!argT.isNull() && "Can't find 'SEL' type"); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys, /*isVariadic=*/true); MsgSendStretFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthMsgSendSuperStretFunctionDecl - // id objc_msgSendSuper_stret(struct objc_super *, SEL op, ...); void RewriteObjC::SynthMsgSendSuperStretFunctionDecl() { IdentifierInfo *msgSendIdent = &Context->Idents.get("objc_msgSendSuper_stret"); SmallVector<QualType, 16> ArgTys; RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("objc_super")); QualType argT = Context->getPointerType(Context->getTagDeclType(RD)); assert(!argT.isNull() && "Can't build 'struct objc_super *' type"); ArgTys.push_back(argT); argT = Context->getObjCSelType(); assert(!argT.isNull() && "Can't find 'SEL' type"); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys, /*isVariadic=*/true); MsgSendSuperStretFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthMsgSendFpretFunctionDecl - double objc_msgSend_fpret(id self, SEL op, ...); void RewriteObjC::SynthMsgSendFpretFunctionDecl() { IdentifierInfo *msgSendIdent = &Context->Idents.get("objc_msgSend_fpret"); SmallVector<QualType, 16> ArgTys; QualType argT = Context->getObjCIdType(); assert(!argT.isNull() && "Can't find 'id' type"); ArgTys.push_back(argT); argT = Context->getObjCSelType(); assert(!argT.isNull() && "Can't find 'SEL' type"); ArgTys.push_back(argT); QualType msgSendType = getSimpleFunctionType(Context->DoubleTy, ArgTys, /*isVariadic=*/true); MsgSendFpretFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), msgSendIdent, msgSendType, nullptr, SC_Extern); } // SynthGetClassFunctionDecl - id objc_getClass(const char *name); void RewriteObjC::SynthGetClassFunctionDecl() { IdentifierInfo *getClassIdent = &Context->Idents.get("objc_getClass"); SmallVector<QualType, 16> ArgTys; ArgTys.push_back(Context->getPointerType(Context->CharTy.withConst())); QualType getClassType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys); GetClassFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), getClassIdent, getClassType, nullptr, SC_Extern); } // SynthGetSuperClassFunctionDecl - Class class_getSuperclass(Class cls); void RewriteObjC::SynthGetSuperClassFunctionDecl() { IdentifierInfo *getSuperClassIdent = &Context->Idents.get("class_getSuperclass"); SmallVector<QualType, 16> ArgTys; ArgTys.push_back(Context->getObjCClassType()); QualType getClassType = getSimpleFunctionType(Context->getObjCClassType(), ArgTys); GetSuperClassFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), getSuperClassIdent, getClassType, nullptr, SC_Extern); } // SynthGetMetaClassFunctionDecl - id objc_getMetaClass(const char *name); void RewriteObjC::SynthGetMetaClassFunctionDecl() { IdentifierInfo *getClassIdent = &Context->Idents.get("objc_getMetaClass"); SmallVector<QualType, 16> ArgTys; ArgTys.push_back(Context->getPointerType(Context->CharTy.withConst())); QualType getClassType = getSimpleFunctionType(Context->getObjCIdType(), ArgTys); GetMetaClassFunctionDecl = FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), getClassIdent, getClassType, nullptr, SC_Extern); } Stmt *RewriteObjC::RewriteObjCStringLiteral(ObjCStringLiteral *Exp) { assert(Exp != nullptr && "Expected non-null ObjCStringLiteral"); QualType strType = getConstantStringStructType(); std::string S = "__NSConstantStringImpl_"; std::string tmpName = InFileName; unsigned i; for (i=0; i < tmpName.length(); i++) { char c = tmpName.at(i); // replace any non-alphanumeric characters with '_'. if (!isAlphanumeric(c)) tmpName[i] = '_'; } S += tmpName; S += "_"; S += utostr(NumObjCStringLiterals++); Preamble += "static __NSConstantStringImpl " + S; Preamble += " __attribute__ ((section (\"__DATA, __cfstring\"))) = {__CFConstantStringClassReference,"; Preamble += "0x000007c8,"; // utf8_str // The pretty printer for StringLiteral handles escape characters properly. std::string prettyBufS; llvm::raw_string_ostream prettyBuf(prettyBufS); Exp->getString()->printPretty(prettyBuf, nullptr, PrintingPolicy(LangOpts)); Preamble += prettyBuf.str(); Preamble += ","; Preamble += utostr(Exp->getString()->getByteLength()) + "};\n"; VarDecl *NewVD = VarDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get(S), strType, nullptr, SC_Static); DeclRefExpr *DRE = new (Context) DeclRefExpr(NewVD, false, strType, VK_LValue, SourceLocation()); Expr *Unop = new (Context) UnaryOperator(DRE, UO_AddrOf, Context->getPointerType(DRE->getType()), VK_RValue, OK_Ordinary, SourceLocation()); // cast to NSConstantString * CastExpr *cast = NoTypeInfoCStyleCastExpr(Context, Exp->getType(), CK_CPointerToObjCPointerCast, Unop); ReplaceStmt(Exp, cast); // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return cast; } // struct objc_super { struct objc_object *receiver; struct objc_class *super; }; QualType RewriteObjC::getSuperStructType() { if (!SuperStructDecl) { SuperStructDecl = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("objc_super")); QualType FieldTypes[2]; // struct objc_object *receiver; FieldTypes[0] = Context->getObjCIdType(); // struct objc_class *super; FieldTypes[1] = Context->getObjCClassType(); // Create fields for (unsigned i = 0; i < 2; ++i) { SuperStructDecl->addDecl(FieldDecl::Create(*Context, SuperStructDecl, SourceLocation(), SourceLocation(), nullptr, FieldTypes[i], nullptr, /*BitWidth=*/nullptr, /*Mutable=*/false, ICIS_NoInit)); } SuperStructDecl->completeDefinition(); } return Context->getTagDeclType(SuperStructDecl); } QualType RewriteObjC::getConstantStringStructType() { if (!ConstantStringDecl) { ConstantStringDecl = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("__NSConstantStringImpl")); QualType FieldTypes[4]; // struct objc_object *receiver; FieldTypes[0] = Context->getObjCIdType(); // int flags; FieldTypes[1] = Context->IntTy; // char *str; FieldTypes[2] = Context->getPointerType(Context->CharTy); // long length; FieldTypes[3] = Context->LongTy; // Create fields for (unsigned i = 0; i < 4; ++i) { ConstantStringDecl->addDecl(FieldDecl::Create(*Context, ConstantStringDecl, SourceLocation(), SourceLocation(), nullptr, FieldTypes[i], nullptr, /*BitWidth=*/nullptr, /*Mutable=*/true, ICIS_NoInit)); } ConstantStringDecl->completeDefinition(); } return Context->getTagDeclType(ConstantStringDecl); } CallExpr *RewriteObjC::SynthMsgSendStretCallExpr(FunctionDecl *MsgSendStretFlavor, QualType msgSendType, QualType returnType, SmallVectorImpl<QualType> &ArgTypes, SmallVectorImpl<Expr*> &MsgExprs, ObjCMethodDecl *Method) { // Create a reference to the objc_msgSend_stret() declaration. DeclRefExpr *STDRE = new (Context) DeclRefExpr(MsgSendStretFlavor, false, msgSendType, VK_LValue, SourceLocation()); // Need to cast objc_msgSend_stret to "void *" (see above comment). CastExpr *cast = NoTypeInfoCStyleCastExpr(Context, Context->getPointerType(Context->VoidTy), CK_BitCast, STDRE); // Now do the "normal" pointer to function cast. QualType castType = getSimpleFunctionType(returnType, ArgTypes, Method ? Method->isVariadic() : false); castType = Context->getPointerType(castType); cast = NoTypeInfoCStyleCastExpr(Context, castType, CK_BitCast, cast); // Don't forget the parens to enforce the proper binding. ParenExpr *PE = new (Context) ParenExpr(SourceLocation(), SourceLocation(), cast); const FunctionType *FT = msgSendType->getAs<FunctionType>(); CallExpr *STCE = new (Context) CallExpr( *Context, PE, MsgExprs, FT->getReturnType(), VK_RValue, SourceLocation()); return STCE; } Stmt *RewriteObjC::SynthMessageExpr(ObjCMessageExpr *Exp, SourceLocation StartLoc, SourceLocation EndLoc) { if (!SelGetUidFunctionDecl) SynthSelGetUidFunctionDecl(); if (!MsgSendFunctionDecl) SynthMsgSendFunctionDecl(); if (!MsgSendSuperFunctionDecl) SynthMsgSendSuperFunctionDecl(); if (!MsgSendStretFunctionDecl) SynthMsgSendStretFunctionDecl(); if (!MsgSendSuperStretFunctionDecl) SynthMsgSendSuperStretFunctionDecl(); if (!MsgSendFpretFunctionDecl) SynthMsgSendFpretFunctionDecl(); if (!GetClassFunctionDecl) SynthGetClassFunctionDecl(); if (!GetSuperClassFunctionDecl) SynthGetSuperClassFunctionDecl(); if (!GetMetaClassFunctionDecl) SynthGetMetaClassFunctionDecl(); // default to objc_msgSend(). FunctionDecl *MsgSendFlavor = MsgSendFunctionDecl; // May need to use objc_msgSend_stret() as well. FunctionDecl *MsgSendStretFlavor = nullptr; if (ObjCMethodDecl *mDecl = Exp->getMethodDecl()) { QualType resultType = mDecl->getReturnType(); if (resultType->isRecordType()) MsgSendStretFlavor = MsgSendStretFunctionDecl; else if (resultType->isRealFloatingType()) MsgSendFlavor = MsgSendFpretFunctionDecl; } // Synthesize a call to objc_msgSend(). SmallVector<Expr*, 8> MsgExprs; switch (Exp->getReceiverKind()) { case ObjCMessageExpr::SuperClass: { MsgSendFlavor = MsgSendSuperFunctionDecl; if (MsgSendStretFlavor) MsgSendStretFlavor = MsgSendSuperStretFunctionDecl; assert(MsgSendFlavor && "MsgSendFlavor is NULL!"); ObjCInterfaceDecl *ClassDecl = CurMethodDef->getClassInterface(); SmallVector<Expr*, 4> InitExprs; // set the receiver to self, the first argument to all methods. InitExprs.push_back( NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK_BitCast, new (Context) DeclRefExpr(CurMethodDef->getSelfDecl(), false, Context->getObjCIdType(), VK_RValue, SourceLocation())) ); // set the 'receiver'. // (id)class_getSuperclass((Class)objc_getClass("CurrentClass")) SmallVector<Expr*, 8> ClsExprs; ClsExprs.push_back(getStringLiteral(ClassDecl->getIdentifier()->getName())); CallExpr *Cls = SynthesizeCallToFunctionDecl(GetMetaClassFunctionDecl, &ClsExprs[0], ClsExprs.size(), StartLoc, EndLoc); // (Class)objc_getClass("CurrentClass") CastExpr *ArgExpr = NoTypeInfoCStyleCastExpr(Context, Context->getObjCClassType(), CK_BitCast, Cls); ClsExprs.clear(); ClsExprs.push_back(ArgExpr); Cls = SynthesizeCallToFunctionDecl(GetSuperClassFunctionDecl, &ClsExprs[0], ClsExprs.size(), StartLoc, EndLoc); // (id)class_getSuperclass((Class)objc_getClass("CurrentClass")) // To turn off a warning, type-cast to 'id' InitExprs.push_back( // set 'super class', using class_getSuperclass(). NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK_BitCast, Cls)); // struct objc_super QualType superType = getSuperStructType(); Expr *SuperRep; if (LangOpts.MicrosoftExt) { SynthSuperConstructorFunctionDecl(); // Simulate a constructor call... DeclRefExpr *DRE = new (Context) DeclRefExpr(SuperConstructorFunctionDecl, false, superType, VK_LValue, SourceLocation()); SuperRep = new (Context) CallExpr(*Context, DRE, InitExprs, superType, VK_LValue, SourceLocation()); // The code for super is a little tricky to prevent collision with // the structure definition in the header. The rewriter has it's own // internal definition (__rw_objc_super) that is uses. This is why // we need the cast below. For example: // (struct objc_super *)&__rw_objc_super((id)self, (id)objc_getClass("SUPER")) // SuperRep = new (Context) UnaryOperator(SuperRep, UO_AddrOf, Context->getPointerType(SuperRep->getType()), VK_RValue, OK_Ordinary, SourceLocation()); SuperRep = NoTypeInfoCStyleCastExpr(Context, Context->getPointerType(superType), CK_BitCast, SuperRep); } else { // (struct objc_super) { <exprs from above> } InitListExpr *ILE = new (Context) InitListExpr(*Context, SourceLocation(), InitExprs, SourceLocation()); TypeSourceInfo *superTInfo = Context->getTrivialTypeSourceInfo(superType); SuperRep = new (Context) CompoundLiteralExpr(SourceLocation(), superTInfo, superType, VK_LValue, ILE, false); // struct objc_super * SuperRep = new (Context) UnaryOperator(SuperRep, UO_AddrOf, Context->getPointerType(SuperRep->getType()), VK_RValue, OK_Ordinary, SourceLocation()); } MsgExprs.push_back(SuperRep); break; } case ObjCMessageExpr::Class: { SmallVector<Expr*, 8> ClsExprs; ObjCInterfaceDecl *Class = Exp->getClassReceiver()->getAs<ObjCObjectType>()->getInterface(); IdentifierInfo *clsName = Class->getIdentifier(); ClsExprs.push_back(getStringLiteral(clsName->getName())); CallExpr *Cls = SynthesizeCallToFunctionDecl(GetClassFunctionDecl, &ClsExprs[0], ClsExprs.size(), StartLoc, EndLoc); MsgExprs.push_back(Cls); break; } case ObjCMessageExpr::SuperInstance:{ MsgSendFlavor = MsgSendSuperFunctionDecl; if (MsgSendStretFlavor) MsgSendStretFlavor = MsgSendSuperStretFunctionDecl; assert(MsgSendFlavor && "MsgSendFlavor is NULL!"); ObjCInterfaceDecl *ClassDecl = CurMethodDef->getClassInterface(); SmallVector<Expr*, 4> InitExprs; InitExprs.push_back( NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK_BitCast, new (Context) DeclRefExpr(CurMethodDef->getSelfDecl(), false, Context->getObjCIdType(), VK_RValue, SourceLocation())) ); // set the 'receiver'. // (id)class_getSuperclass((Class)objc_getClass("CurrentClass")) SmallVector<Expr*, 8> ClsExprs; ClsExprs.push_back(getStringLiteral(ClassDecl->getIdentifier()->getName())); CallExpr *Cls = SynthesizeCallToFunctionDecl(GetClassFunctionDecl, &ClsExprs[0], ClsExprs.size(), StartLoc, EndLoc); // (Class)objc_getClass("CurrentClass") CastExpr *ArgExpr = NoTypeInfoCStyleCastExpr(Context, Context->getObjCClassType(), CK_BitCast, Cls); ClsExprs.clear(); ClsExprs.push_back(ArgExpr); Cls = SynthesizeCallToFunctionDecl(GetSuperClassFunctionDecl, &ClsExprs[0], ClsExprs.size(), StartLoc, EndLoc); // (id)class_getSuperclass((Class)objc_getClass("CurrentClass")) // To turn off a warning, type-cast to 'id' InitExprs.push_back( // set 'super class', using class_getSuperclass(). NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK_BitCast, Cls)); // struct objc_super QualType superType = getSuperStructType(); Expr *SuperRep; if (LangOpts.MicrosoftExt) { SynthSuperConstructorFunctionDecl(); // Simulate a constructor call... DeclRefExpr *DRE = new (Context) DeclRefExpr(SuperConstructorFunctionDecl, false, superType, VK_LValue, SourceLocation()); SuperRep = new (Context) CallExpr(*Context, DRE, InitExprs, superType, VK_LValue, SourceLocation()); // The code for super is a little tricky to prevent collision with // the structure definition in the header. The rewriter has it's own // internal definition (__rw_objc_super) that is uses. This is why // we need the cast below. For example: // (struct objc_super *)&__rw_objc_super((id)self, (id)objc_getClass("SUPER")) // SuperRep = new (Context) UnaryOperator(SuperRep, UO_AddrOf, Context->getPointerType(SuperRep->getType()), VK_RValue, OK_Ordinary, SourceLocation()); SuperRep = NoTypeInfoCStyleCastExpr(Context, Context->getPointerType(superType), CK_BitCast, SuperRep); } else { // (struct objc_super) { <exprs from above> } InitListExpr *ILE = new (Context) InitListExpr(*Context, SourceLocation(), InitExprs, SourceLocation()); TypeSourceInfo *superTInfo = Context->getTrivialTypeSourceInfo(superType); SuperRep = new (Context) CompoundLiteralExpr(SourceLocation(), superTInfo, superType, VK_RValue, ILE, false); } MsgExprs.push_back(SuperRep); break; } case ObjCMessageExpr::Instance: { // Remove all type-casts because it may contain objc-style types; e.g. // Foo<Proto> *. Expr *recExpr = Exp->getInstanceReceiver(); while (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(recExpr)) recExpr = CE->getSubExpr(); CastKind CK = recExpr->getType()->isObjCObjectPointerType() ? CK_BitCast : recExpr->getType()->isBlockPointerType() ? CK_BlockPointerToObjCPointerCast : CK_CPointerToObjCPointerCast; recExpr = NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK, recExpr); MsgExprs.push_back(recExpr); break; } } // Create a call to sel_registerName("selName"), it will be the 2nd argument. SmallVector<Expr*, 8> SelExprs; SelExprs.push_back(getStringLiteral(Exp->getSelector().getAsString())); CallExpr *SelExp = SynthesizeCallToFunctionDecl(SelGetUidFunctionDecl, &SelExprs[0], SelExprs.size(), StartLoc, EndLoc); MsgExprs.push_back(SelExp); // Now push any user supplied arguments. for (unsigned i = 0; i < Exp->getNumArgs(); i++) { Expr *userExpr = Exp->getArg(i); // Make all implicit casts explicit...ICE comes in handy:-) if (ImplicitCastExpr *ICE = dyn_cast<ImplicitCastExpr>(userExpr)) { // Reuse the ICE type, it is exactly what the doctor ordered. QualType type = ICE->getType(); if (needToScanForQualifiers(type)) type = Context->getObjCIdType(); // Make sure we convert "type (^)(...)" to "type (*)(...)". (void)convertBlockPointerToFunctionPointer(type); const Expr *SubExpr = ICE->IgnoreParenImpCasts(); CastKind CK; if (SubExpr->getType()->isIntegralType(*Context) && type->isBooleanType()) { CK = CK_IntegralToBoolean; } else if (type->isObjCObjectPointerType()) { if (SubExpr->getType()->isBlockPointerType()) { CK = CK_BlockPointerToObjCPointerCast; } else if (SubExpr->getType()->isPointerType()) { CK = CK_CPointerToObjCPointerCast; } else { CK = CK_BitCast; } } else { CK = CK_BitCast; } userExpr = NoTypeInfoCStyleCastExpr(Context, type, CK, userExpr); } // Make id<P...> cast into an 'id' cast. else if (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(userExpr)) { if (CE->getType()->isObjCQualifiedIdType()) { while ((CE = dyn_cast<CStyleCastExpr>(userExpr))) userExpr = CE->getSubExpr(); CastKind CK; if (userExpr->getType()->isIntegralType(*Context)) { CK = CK_IntegralToPointer; } else if (userExpr->getType()->isBlockPointerType()) { CK = CK_BlockPointerToObjCPointerCast; } else if (userExpr->getType()->isPointerType()) { CK = CK_CPointerToObjCPointerCast; } else { CK = CK_BitCast; } userExpr = NoTypeInfoCStyleCastExpr(Context, Context->getObjCIdType(), CK, userExpr); } } MsgExprs.push_back(userExpr); // We've transferred the ownership to MsgExprs. For now, we *don't* null // out the argument in the original expression (since we aren't deleting // the ObjCMessageExpr). See RewritePropertyOrImplicitSetter() usage for more info. //Exp->setArg(i, 0); } // Generate the funky cast. CastExpr *cast; SmallVector<QualType, 8> ArgTypes; QualType returnType; // Push 'id' and 'SEL', the 2 implicit arguments. if (MsgSendFlavor == MsgSendSuperFunctionDecl) ArgTypes.push_back(Context->getPointerType(getSuperStructType())); else ArgTypes.push_back(Context->getObjCIdType()); ArgTypes.push_back(Context->getObjCSelType()); if (ObjCMethodDecl *OMD = Exp->getMethodDecl()) { // Push any user argument types. for (const auto *PI : OMD->params()) { QualType t = PI->getType()->isObjCQualifiedIdType() ? Context->getObjCIdType() : PI->getType(); // Make sure we convert "t (^)(...)" to "t (*)(...)". (void)convertBlockPointerToFunctionPointer(t); ArgTypes.push_back(t); } returnType = Exp->getType(); convertToUnqualifiedObjCType(returnType); (void)convertBlockPointerToFunctionPointer(returnType); } else { returnType = Context->getObjCIdType(); } // Get the type, we will need to reference it in a couple spots. QualType msgSendType = MsgSendFlavor->getType(); // Create a reference to the objc_msgSend() declaration. DeclRefExpr *DRE = new (Context) DeclRefExpr(MsgSendFlavor, false, msgSendType, VK_LValue, SourceLocation()); // Need to cast objc_msgSend to "void *" (to workaround a GCC bandaid). // If we don't do this cast, we get the following bizarre warning/note: // xx.m:13: warning: function called through a non-compatible type // xx.m:13: note: if this code is reached, the program will abort cast = NoTypeInfoCStyleCastExpr(Context, Context->getPointerType(Context->VoidTy), CK_BitCast, DRE); // Now do the "normal" pointer to function cast. // If we don't have a method decl, force a variadic cast. const ObjCMethodDecl *MD = Exp->getMethodDecl(); QualType castType = getSimpleFunctionType(returnType, ArgTypes, MD ? MD->isVariadic() : true); castType = Context->getPointerType(castType); cast = NoTypeInfoCStyleCastExpr(Context, castType, CK_BitCast, cast); // Don't forget the parens to enforce the proper binding. ParenExpr *PE = new (Context) ParenExpr(StartLoc, EndLoc, cast); const FunctionType *FT = msgSendType->getAs<FunctionType>(); CallExpr *CE = new (Context) CallExpr(*Context, PE, MsgExprs, FT->getReturnType(), VK_RValue, EndLoc); Stmt *ReplacingStmt = CE; if (MsgSendStretFlavor) { // We have the method which returns a struct/union. Must also generate // call to objc_msgSend_stret and hang both varieties on a conditional // expression which dictate which one to envoke depending on size of // method's return type. CallExpr *STCE = SynthMsgSendStretCallExpr(MsgSendStretFlavor, msgSendType, returnType, ArgTypes, MsgExprs, Exp->getMethodDecl()); // Build sizeof(returnType) UnaryExprOrTypeTraitExpr *sizeofExpr = new (Context) UnaryExprOrTypeTraitExpr(UETT_SizeOf, Context->getTrivialTypeSourceInfo(returnType), Context->getSizeType(), SourceLocation(), SourceLocation()); // (sizeof(returnType) <= 8 ? objc_msgSend(...) : objc_msgSend_stret(...)) // FIXME: Value of 8 is base on ppc32/x86 ABI for the most common cases. // For X86 it is more complicated and some kind of target specific routine // is needed to decide what to do. unsigned IntSize = static_cast<unsigned>(Context->getTypeSize(Context->IntTy)); IntegerLiteral *limit = IntegerLiteral::Create(*Context, llvm::APInt(IntSize, 8), Context->IntTy, SourceLocation()); BinaryOperator *lessThanExpr = new (Context) BinaryOperator(sizeofExpr, limit, BO_LE, Context->IntTy, VK_RValue, OK_Ordinary, SourceLocation(), false); // (sizeof(returnType) <= 8 ? objc_msgSend(...) : objc_msgSend_stret(...)) ConditionalOperator *CondExpr = new (Context) ConditionalOperator(lessThanExpr, SourceLocation(), CE, SourceLocation(), STCE, returnType, VK_RValue, OK_Ordinary); ReplacingStmt = new (Context) ParenExpr(SourceLocation(), SourceLocation(), CondExpr); } // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return ReplacingStmt; } Stmt *RewriteObjC::RewriteMessageExpr(ObjCMessageExpr *Exp) { Stmt *ReplacingStmt = SynthMessageExpr(Exp, Exp->getLocStart(), Exp->getLocEnd()); // Now do the actual rewrite. ReplaceStmt(Exp, ReplacingStmt); // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return ReplacingStmt; } // typedef struct objc_object Protocol; QualType RewriteObjC::getProtocolType() { if (!ProtocolTypeDecl) { TypeSourceInfo *TInfo = Context->getTrivialTypeSourceInfo(Context->getObjCIdType()); ProtocolTypeDecl = TypedefDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("Protocol"), TInfo); } return Context->getTypeDeclType(ProtocolTypeDecl); } /// RewriteObjCProtocolExpr - Rewrite a protocol expression into /// a synthesized/forward data reference (to the protocol's metadata). /// The forward references (and metadata) are generated in /// RewriteObjC::HandleTranslationUnit(). Stmt *RewriteObjC::RewriteObjCProtocolExpr(ObjCProtocolExpr *Exp) { std::string Name = "_OBJC_PROTOCOL_" + Exp->getProtocol()->getNameAsString(); IdentifierInfo *ID = &Context->Idents.get(Name); VarDecl *VD = VarDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), ID, getProtocolType(), nullptr, SC_Extern); DeclRefExpr *DRE = new (Context) DeclRefExpr(VD, false, getProtocolType(), VK_LValue, SourceLocation()); Expr *DerefExpr = new (Context) UnaryOperator(DRE, UO_AddrOf, Context->getPointerType(DRE->getType()), VK_RValue, OK_Ordinary, SourceLocation()); CastExpr *castExpr = NoTypeInfoCStyleCastExpr(Context, DerefExpr->getType(), CK_BitCast, DerefExpr); ReplaceStmt(Exp, castExpr); ProtocolExprDecls.insert(Exp->getProtocol()->getCanonicalDecl()); // delete Exp; leak for now, see RewritePropertyOrImplicitSetter() usage for more info. return castExpr; } bool RewriteObjC::BufferContainsPPDirectives(const char *startBuf, const char *endBuf) { while (startBuf < endBuf) { if (*startBuf == '#') { // Skip whitespace. for (++startBuf; startBuf[0] == ' ' || startBuf[0] == '\t'; ++startBuf) ; if (!strncmp(startBuf, "if", strlen("if")) || !strncmp(startBuf, "ifdef", strlen("ifdef")) || !strncmp(startBuf, "ifndef", strlen("ifndef")) || !strncmp(startBuf, "define", strlen("define")) || !strncmp(startBuf, "undef", strlen("undef")) || !strncmp(startBuf, "else", strlen("else")) || !strncmp(startBuf, "elif", strlen("elif")) || !strncmp(startBuf, "endif", strlen("endif")) || !strncmp(startBuf, "pragma", strlen("pragma")) || !strncmp(startBuf, "include", strlen("include")) || !strncmp(startBuf, "import", strlen("import")) || !strncmp(startBuf, "include_next", strlen("include_next"))) return true; } startBuf++; } return false; } /// RewriteObjCInternalStruct - Rewrite one internal struct corresponding to /// an objective-c class with ivars. void RewriteObjC::RewriteObjCInternalStruct(ObjCInterfaceDecl *CDecl, std::string &Result) { assert(CDecl && "Class missing in SynthesizeObjCInternalStruct"); assert(CDecl->getName() != "" && "Name missing in SynthesizeObjCInternalStruct"); // Do not synthesize more than once. if (ObjCSynthesizedStructs.count(CDecl)) return; ObjCInterfaceDecl *RCDecl = CDecl->getSuperClass(); int NumIvars = CDecl->ivar_size(); SourceLocation LocStart = CDecl->getLocStart(); SourceLocation LocEnd = CDecl->getEndOfDefinitionLoc(); const char *startBuf = SM->getCharacterData(LocStart); const char *endBuf = SM->getCharacterData(LocEnd); // If no ivars and no root or if its root, directly or indirectly, // have no ivars (thus not synthesized) then no need to synthesize this class. if ((!CDecl->isThisDeclarationADefinition() || NumIvars == 0) && (!RCDecl || !ObjCSynthesizedStructs.count(RCDecl))) { endBuf += Lexer::MeasureTokenLength(LocEnd, *SM, LangOpts); ReplaceText(LocStart, endBuf-startBuf, Result); return; } // FIXME: This has potential of causing problem. If // SynthesizeObjCInternalStruct is ever called recursively. Result += "\nstruct "; Result += CDecl->getNameAsString(); if (LangOpts.MicrosoftExt) Result += "_IMPL"; if (NumIvars > 0) { const char *cursor = strchr(startBuf, '{'); assert((cursor && endBuf) && "SynthesizeObjCInternalStruct - malformed @interface"); // If the buffer contains preprocessor directives, we do more fine-grained // rewrites. This is intended to fix code that looks like (which occurs in // NSURL.h, for example): // // #ifdef XYZ // @interface Foo : NSObject // #else // @interface FooBar : NSObject // #endif // { // int i; // } // @end // // This clause is segregated to avoid breaking the common case. if (BufferContainsPPDirectives(startBuf, cursor)) { SourceLocation L = RCDecl ? CDecl->getSuperClassLoc() : CDecl->getAtStartLoc(); const char *endHeader = SM->getCharacterData(L); endHeader += Lexer::MeasureTokenLength(L, *SM, LangOpts); if (CDecl->protocol_begin() != CDecl->protocol_end()) { // advance to the end of the referenced protocols. while (endHeader < cursor && *endHeader != '>') endHeader++; endHeader++; } // rewrite the original header ReplaceText(LocStart, endHeader-startBuf, Result); } else { // rewrite the original header *without* disturbing the '{' ReplaceText(LocStart, cursor-startBuf, Result); } if (RCDecl && ObjCSynthesizedStructs.count(RCDecl)) { Result = "\n struct "; Result += RCDecl->getNameAsString(); Result += "_IMPL "; Result += RCDecl->getNameAsString(); Result += "_IVARS;\n"; // insert the super class structure definition. SourceLocation OnePastCurly = LocStart.getLocWithOffset(cursor-startBuf+1); InsertText(OnePastCurly, Result); } cursor++; // past '{' // Now comment out any visibility specifiers. while (cursor < endBuf) { if (*cursor == '@') { SourceLocation atLoc = LocStart.getLocWithOffset(cursor-startBuf); // Skip whitespace. for (++cursor; cursor[0] == ' ' || cursor[0] == '\t'; ++cursor) /*scan*/; // FIXME: presence of @public, etc. inside comment results in // this transformation as well, which is still correct c-code. if (!strncmp(cursor, "public", strlen("public")) || !strncmp(cursor, "private", strlen("private")) || !strncmp(cursor, "package", strlen("package")) || !strncmp(cursor, "protected", strlen("protected"))) InsertText(atLoc, "// "); } // FIXME: If there are cases where '<' is used in ivar declaration part // of user code, then scan the ivar list and use needToScanForQualifiers // for type checking. else if (*cursor == '<') { SourceLocation atLoc = LocStart.getLocWithOffset(cursor-startBuf); InsertText(atLoc, "/* "); cursor = strchr(cursor, '>'); cursor++; atLoc = LocStart.getLocWithOffset(cursor-startBuf); InsertText(atLoc, " */"); } else if (*cursor == '^') { // rewrite block specifier. SourceLocation caretLoc = LocStart.getLocWithOffset(cursor-startBuf); ReplaceText(caretLoc, 1, "*"); } cursor++; } // Don't forget to add a ';'!! InsertText(LocEnd.getLocWithOffset(1), ";"); } else { // we don't have any instance variables - insert super struct. endBuf += Lexer::MeasureTokenLength(LocEnd, *SM, LangOpts); Result += " {\n struct "; Result += RCDecl->getNameAsString(); Result += "_IMPL "; Result += RCDecl->getNameAsString(); Result += "_IVARS;\n};\n"; ReplaceText(LocStart, endBuf-startBuf, Result); } // Mark this struct as having been generated. if (!ObjCSynthesizedStructs.insert(CDecl).second) llvm_unreachable("struct already synthesize- SynthesizeObjCInternalStruct"); } //===----------------------------------------------------------------------===// // Meta Data Emission //===----------------------------------------------------------------------===// /// RewriteImplementations - This routine rewrites all method implementations /// and emits meta-data. void RewriteObjC::RewriteImplementations() { int ClsDefCount = ClassImplementation.size(); int CatDefCount = CategoryImplementation.size(); // Rewrite implemented methods for (int i = 0; i < ClsDefCount; i++) RewriteImplementationDecl(ClassImplementation[i]); for (int i = 0; i < CatDefCount; i++) RewriteImplementationDecl(CategoryImplementation[i]); } void RewriteObjC::RewriteByRefString(std::string &ResultStr, const std::string &Name, ValueDecl *VD, bool def) { assert(BlockByRefDeclNo.count(VD) && "RewriteByRefString: ByRef decl missing"); if (def) ResultStr += "struct "; ResultStr += "__Block_byref_" + Name + "_" + utostr(BlockByRefDeclNo[VD]) ; } static bool HasLocalVariableExternalStorage(ValueDecl *VD) { if (VarDecl *Var = dyn_cast<VarDecl>(VD)) return (Var->isFunctionOrMethodVarDecl() && !Var->hasLocalStorage()); return false; } std::string RewriteObjC::SynthesizeBlockFunc(BlockExpr *CE, int i, StringRef funcName, std::string Tag) { const FunctionType *AFT = CE->getFunctionType(); QualType RT = AFT->getReturnType(); std::string StructRef = "struct " + Tag; std::string S = "static " + RT.getAsString(Context->getPrintingPolicy()) + " __" + funcName.str() + "_" + "block_func_" + utostr(i); BlockDecl *BD = CE->getBlockDecl(); if (isa<FunctionNoProtoType>(AFT)) { // No user-supplied arguments. Still need to pass in a pointer to the // block (to reference imported block decl refs). S += "(" + StructRef + " *__cself)"; } else if (BD->param_empty()) { S += "(" + StructRef + " *__cself)"; } else { const FunctionProtoType *FT = cast<FunctionProtoType>(AFT); assert(FT && "SynthesizeBlockFunc: No function proto"); S += '('; // first add the implicit argument. S += StructRef + " *__cself, "; std::string ParamStr; for (BlockDecl::param_iterator AI = BD->param_begin(), E = BD->param_end(); AI != E; ++AI) { if (AI != BD->param_begin()) S += ", "; ParamStr = (*AI)->getNameAsString(); QualType QT = (*AI)->getType(); (void)convertBlockPointerToFunctionPointer(QT); QT.getAsStringInternal(ParamStr, Context->getPrintingPolicy()); S += ParamStr; } if (FT->isVariadic()) { if (!BD->param_empty()) S += ", "; S += "..."; } S += ')'; } S += " {\n"; // Create local declarations to avoid rewriting all closure decl ref exprs. // First, emit a declaration for all "by ref" decls. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByRefDecls.begin(), E = BlockByRefDecls.end(); I != E; ++I) { S += " "; std::string Name = (*I)->getNameAsString(); std::string TypeString; RewriteByRefString(TypeString, Name, (*I)); TypeString += " *"; Name = TypeString + Name; S += Name + " = __cself->" + (*I)->getNameAsString() + "; // bound by ref\n"; } // Next, emit a declaration for all "by copy" declarations. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByCopyDecls.begin(), E = BlockByCopyDecls.end(); I != E; ++I) { S += " "; // Handle nested closure invocation. For example: // // void (^myImportedClosure)(void); // myImportedClosure = ^(void) { setGlobalInt(x + y); }; // // void (^anotherClosure)(void); // anotherClosure = ^(void) { // myImportedClosure(); // import and invoke the closure // }; // if (isTopLevelBlockPointerType((*I)->getType())) { RewriteBlockPointerTypeVariable(S, (*I)); S += " = ("; RewriteBlockPointerType(S, (*I)->getType()); S += ")"; S += "__cself->" + (*I)->getNameAsString() + "; // bound by copy\n"; } else { std::string Name = (*I)->getNameAsString(); QualType QT = (*I)->getType(); if (HasLocalVariableExternalStorage(*I)) QT = Context->getPointerType(QT); QT.getAsStringInternal(Name, Context->getPrintingPolicy()); S += Name + " = __cself->" + (*I)->getNameAsString() + "; // bound by copy\n"; } } std::string RewrittenStr = RewrittenBlockExprs[CE]; const char *cstr = RewrittenStr.c_str(); while (*cstr++ != '{') ; S += cstr; S += "\n"; return S; } std::string RewriteObjC::SynthesizeBlockHelperFuncs(BlockExpr *CE, int i, StringRef funcName, std::string Tag) { std::string StructRef = "struct " + Tag; std::string S = "static void __"; S += funcName; S += "_block_copy_" + utostr(i); S += "(" + StructRef; S += "*dst, " + StructRef; S += "*src) {"; for (ValueDecl *VD : ImportedBlockDecls) { S += "_Block_object_assign((void*)&dst->"; S += VD->getNameAsString(); S += ", (void*)src->"; S += VD->getNameAsString(); if (BlockByRefDeclsPtrSet.count(VD)) S += ", " + utostr(BLOCK_FIELD_IS_BYREF) + "/*BLOCK_FIELD_IS_BYREF*/);"; else if (VD->getType()->isBlockPointerType()) S += ", " + utostr(BLOCK_FIELD_IS_BLOCK) + "/*BLOCK_FIELD_IS_BLOCK*/);"; else S += ", " + utostr(BLOCK_FIELD_IS_OBJECT) + "/*BLOCK_FIELD_IS_OBJECT*/);"; } S += "}\n"; S += "\nstatic void __"; S += funcName; S += "_block_dispose_" + utostr(i); S += "(" + StructRef; S += "*src) {"; for (ValueDecl *VD : ImportedBlockDecls) { S += "_Block_object_dispose((void*)src->"; S += VD->getNameAsString(); if (BlockByRefDeclsPtrSet.count(VD)) S += ", " + utostr(BLOCK_FIELD_IS_BYREF) + "/*BLOCK_FIELD_IS_BYREF*/);"; else if (VD->getType()->isBlockPointerType()) S += ", " + utostr(BLOCK_FIELD_IS_BLOCK) + "/*BLOCK_FIELD_IS_BLOCK*/);"; else S += ", " + utostr(BLOCK_FIELD_IS_OBJECT) + "/*BLOCK_FIELD_IS_OBJECT*/);"; } S += "}\n"; return S; } std::string RewriteObjC::SynthesizeBlockImpl(BlockExpr *CE, std::string Tag, std::string Desc) { std::string S = "\nstruct " + Tag; std::string Constructor = " " + Tag; S += " {\n struct __block_impl impl;\n"; S += " struct " + Desc; S += "* Desc;\n"; Constructor += "(void *fp, "; // Invoke function pointer. Constructor += "struct " + Desc; // Descriptor pointer. Constructor += " *desc"; if (BlockDeclRefs.size()) { // Output all "by copy" declarations. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByCopyDecls.begin(), E = BlockByCopyDecls.end(); I != E; ++I) { S += " "; std::string FieldName = (*I)->getNameAsString(); std::string ArgName = "_" + FieldName; // Handle nested closure invocation. For example: // // void (^myImportedBlock)(void); // myImportedBlock = ^(void) { setGlobalInt(x + y); }; // // void (^anotherBlock)(void); // anotherBlock = ^(void) { // myImportedBlock(); // import and invoke the closure // }; // if (isTopLevelBlockPointerType((*I)->getType())) { S += "struct __block_impl *"; Constructor += ", void *" + ArgName; } else { QualType QT = (*I)->getType(); if (HasLocalVariableExternalStorage(*I)) QT = Context->getPointerType(QT); QT.getAsStringInternal(FieldName, Context->getPrintingPolicy()); QT.getAsStringInternal(ArgName, Context->getPrintingPolicy()); Constructor += ", " + ArgName; } S += FieldName + ";\n"; } // Output all "by ref" declarations. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByRefDecls.begin(), E = BlockByRefDecls.end(); I != E; ++I) { S += " "; std::string FieldName = (*I)->getNameAsString(); std::string ArgName = "_" + FieldName; { std::string TypeString; RewriteByRefString(TypeString, FieldName, (*I)); TypeString += " *"; FieldName = TypeString + FieldName; ArgName = TypeString + ArgName; Constructor += ", " + ArgName; } S += FieldName + "; // by ref\n"; } // Finish writing the constructor. Constructor += ", int flags=0)"; // Initialize all "by copy" arguments. bool firsTime = true; for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByCopyDecls.begin(), E = BlockByCopyDecls.end(); I != E; ++I) { std::string Name = (*I)->getNameAsString(); if (firsTime) { Constructor += " : "; firsTime = false; } else Constructor += ", "; if (isTopLevelBlockPointerType((*I)->getType())) Constructor += Name + "((struct __block_impl *)_" + Name + ")"; else Constructor += Name + "(_" + Name + ")"; } // Initialize all "by ref" arguments. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByRefDecls.begin(), E = BlockByRefDecls.end(); I != E; ++I) { std::string Name = (*I)->getNameAsString(); if (firsTime) { Constructor += " : "; firsTime = false; } else Constructor += ", "; Constructor += Name + "(_" + Name + "->__forwarding)"; } Constructor += " {\n"; if (GlobalVarDecl) Constructor += " impl.isa = &_NSConcreteGlobalBlock;\n"; else Constructor += " impl.isa = &_NSConcreteStackBlock;\n"; Constructor += " impl.Flags = flags;\n impl.FuncPtr = fp;\n"; Constructor += " Desc = desc;\n"; } else { // Finish writing the constructor. Constructor += ", int flags=0) {\n"; if (GlobalVarDecl) Constructor += " impl.isa = &_NSConcreteGlobalBlock;\n"; else Constructor += " impl.isa = &_NSConcreteStackBlock;\n"; Constructor += " impl.Flags = flags;\n impl.FuncPtr = fp;\n"; Constructor += " Desc = desc;\n"; } Constructor += " "; Constructor += "}\n"; S += Constructor; S += "};\n"; return S; } std::string RewriteObjC::SynthesizeBlockDescriptor(std::string DescTag, std::string ImplTag, int i, StringRef FunName, unsigned hasCopy) { std::string S = "\nstatic struct " + DescTag; S += " {\n unsigned long reserved;\n"; S += " unsigned long Block_size;\n"; if (hasCopy) { S += " void (*copy)(struct "; S += ImplTag; S += "*, struct "; S += ImplTag; S += "*);\n"; S += " void (*dispose)(struct "; S += ImplTag; S += "*);\n"; } S += "} "; S += DescTag + "_DATA = { 0, sizeof(struct "; S += ImplTag + ")"; if (hasCopy) { S += ", __" + FunName.str() + "_block_copy_" + utostr(i); S += ", __" + FunName.str() + "_block_dispose_" + utostr(i); } S += "};\n"; return S; } void RewriteObjC::SynthesizeBlockLiterals(SourceLocation FunLocStart, StringRef FunName) { // Insert declaration for the function in which block literal is used. if (CurFunctionDeclToDeclareForBlock && !Blocks.empty()) RewriteBlockLiteralFunctionDecl(CurFunctionDeclToDeclareForBlock); bool RewriteSC = (GlobalVarDecl && !Blocks.empty() && GlobalVarDecl->getStorageClass() == SC_Static && GlobalVarDecl->getType().getCVRQualifiers()); if (RewriteSC) { std::string SC(" void __"); SC += GlobalVarDecl->getNameAsString(); SC += "() {}"; InsertText(FunLocStart, SC); } // Insert closures that were part of the function. for (unsigned i = 0, count=0; i < Blocks.size(); i++) { CollectBlockDeclRefInfo(Blocks[i]); // Need to copy-in the inner copied-in variables not actually used in this // block. for (int j = 0; j < InnerDeclRefsCount[i]; j++) { DeclRefExpr *Exp = InnerDeclRefs[count++]; ValueDecl *VD = Exp->getDecl(); BlockDeclRefs.push_back(Exp); if (!VD->hasAttr<BlocksAttr>() && !BlockByCopyDeclsPtrSet.count(VD)) { BlockByCopyDeclsPtrSet.insert(VD); BlockByCopyDecls.push_back(VD); } if (VD->hasAttr<BlocksAttr>() && !BlockByRefDeclsPtrSet.count(VD)) { BlockByRefDeclsPtrSet.insert(VD); BlockByRefDecls.push_back(VD); } // imported objects in the inner blocks not used in the outer // blocks must be copied/disposed in the outer block as well. if (VD->hasAttr<BlocksAttr>() || VD->getType()->isObjCObjectPointerType() || VD->getType()->isBlockPointerType()) ImportedBlockDecls.insert(VD); } std::string ImplTag = "__" + FunName.str() + "_block_impl_" + utostr(i); std::string DescTag = "__" + FunName.str() + "_block_desc_" + utostr(i); std::string CI = SynthesizeBlockImpl(Blocks[i], ImplTag, DescTag); InsertText(FunLocStart, CI); std::string CF = SynthesizeBlockFunc(Blocks[i], i, FunName, ImplTag); InsertText(FunLocStart, CF); if (ImportedBlockDecls.size()) { std::string HF = SynthesizeBlockHelperFuncs(Blocks[i], i, FunName, ImplTag); InsertText(FunLocStart, HF); } std::string BD = SynthesizeBlockDescriptor(DescTag, ImplTag, i, FunName, ImportedBlockDecls.size() > 0); InsertText(FunLocStart, BD); BlockDeclRefs.clear(); BlockByRefDecls.clear(); BlockByRefDeclsPtrSet.clear(); BlockByCopyDecls.clear(); BlockByCopyDeclsPtrSet.clear(); ImportedBlockDecls.clear(); } if (RewriteSC) { // Must insert any 'const/volatile/static here. Since it has been // removed as result of rewriting of block literals. std::string SC; if (GlobalVarDecl->getStorageClass() == SC_Static) SC = "static "; if (GlobalVarDecl->getType().isConstQualified()) SC += "const "; if (GlobalVarDecl->getType().isVolatileQualified()) SC += "volatile "; if (GlobalVarDecl->getType().isRestrictQualified()) SC += "restrict "; InsertText(FunLocStart, SC); } Blocks.clear(); InnerDeclRefsCount.clear(); InnerDeclRefs.clear(); RewrittenBlockExprs.clear(); } void RewriteObjC::InsertBlockLiteralsWithinFunction(FunctionDecl *FD) { SourceLocation FunLocStart = FD->getTypeSpecStartLoc(); StringRef FuncName = FD->getName(); SynthesizeBlockLiterals(FunLocStart, FuncName); } static void BuildUniqueMethodName(std::string &Name, ObjCMethodDecl *MD) { ObjCInterfaceDecl *IFace = MD->getClassInterface(); Name = IFace->getName(); Name += "__" + MD->getSelector().getAsString(); // Convert colons to underscores. std::string::size_type loc = 0; while ((loc = Name.find(":", loc)) != std::string::npos) Name.replace(loc, 1, "_"); } void RewriteObjC::InsertBlockLiteralsWithinMethod(ObjCMethodDecl *MD) { //fprintf(stderr,"In InsertBlockLiteralsWitinMethod\n"); //SourceLocation FunLocStart = MD->getLocStart(); SourceLocation FunLocStart = MD->getLocStart(); std::string FuncName; BuildUniqueMethodName(FuncName, MD); SynthesizeBlockLiterals(FunLocStart, FuncName); } void RewriteObjC::GetBlockDeclRefExprs(Stmt *S) { for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) { if (BlockExpr *CBE = dyn_cast<BlockExpr>(*CI)) GetBlockDeclRefExprs(CBE->getBody()); else GetBlockDeclRefExprs(*CI); } // Handle specific things. if (DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(S)) if (DRE->refersToEnclosingVariableOrCapture() || HasLocalVariableExternalStorage(DRE->getDecl())) // FIXME: Handle enums. BlockDeclRefs.push_back(DRE); return; } void RewriteObjC::GetInnerBlockDeclRefExprs(Stmt *S, SmallVectorImpl<DeclRefExpr *> &InnerBlockDeclRefs, llvm::SmallPtrSetImpl<const DeclContext *> &InnerContexts) { for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) { if (BlockExpr *CBE = dyn_cast<BlockExpr>(*CI)) { InnerContexts.insert(cast<DeclContext>(CBE->getBlockDecl())); GetInnerBlockDeclRefExprs(CBE->getBody(), InnerBlockDeclRefs, InnerContexts); } else GetInnerBlockDeclRefExprs(*CI, InnerBlockDeclRefs, InnerContexts); } // Handle specific things. if (DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(S)) { if (DRE->refersToEnclosingVariableOrCapture() || HasLocalVariableExternalStorage(DRE->getDecl())) { if (!InnerContexts.count(DRE->getDecl()->getDeclContext())) InnerBlockDeclRefs.push_back(DRE); if (VarDecl *Var = cast<VarDecl>(DRE->getDecl())) if (Var->isFunctionOrMethodVarDecl()) ImportedLocalExternalDecls.insert(Var); } } return; } /// convertFunctionTypeOfBlocks - This routine converts a function type /// whose result type may be a block pointer or whose argument type(s) /// might be block pointers to an equivalent function type replacing /// all block pointers to function pointers. QualType RewriteObjC::convertFunctionTypeOfBlocks(const FunctionType *FT) { const FunctionProtoType *FTP = dyn_cast<FunctionProtoType>(FT); // FTP will be null for closures that don't take arguments. // Generate a funky cast. SmallVector<QualType, 8> ArgTypes; QualType Res = FT->getReturnType(); bool HasBlockType = convertBlockPointerToFunctionPointer(Res); if (FTP) { for (auto &I : FTP->param_types()) { QualType t = I; // Make sure we convert "t (^)(...)" to "t (*)(...)". if (convertBlockPointerToFunctionPointer(t)) HasBlockType = true; ArgTypes.push_back(t); } } QualType FuncType; // FIXME. Does this work if block takes no argument but has a return type // which is of block type? if (HasBlockType) FuncType = getSimpleFunctionType(Res, ArgTypes); else FuncType = QualType(FT, 0); return FuncType; } Stmt *RewriteObjC::SynthesizeBlockCall(CallExpr *Exp, const Expr *BlockExp) { // Navigate to relevant type information. const BlockPointerType *CPT = nullptr; if (const DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(BlockExp)) { CPT = DRE->getType()->getAs<BlockPointerType>(); } else if (const MemberExpr *MExpr = dyn_cast<MemberExpr>(BlockExp)) { CPT = MExpr->getType()->getAs<BlockPointerType>(); } else if (const ParenExpr *PRE = dyn_cast<ParenExpr>(BlockExp)) { return SynthesizeBlockCall(Exp, PRE->getSubExpr()); } else if (const ImplicitCastExpr *IEXPR = dyn_cast<ImplicitCastExpr>(BlockExp)) CPT = IEXPR->getType()->getAs<BlockPointerType>(); else if (const ConditionalOperator *CEXPR = dyn_cast<ConditionalOperator>(BlockExp)) { Expr *LHSExp = CEXPR->getLHS(); Stmt *LHSStmt = SynthesizeBlockCall(Exp, LHSExp); Expr *RHSExp = CEXPR->getRHS(); Stmt *RHSStmt = SynthesizeBlockCall(Exp, RHSExp); Expr *CONDExp = CEXPR->getCond(); ConditionalOperator *CondExpr = new (Context) ConditionalOperator(CONDExp, SourceLocation(), cast<Expr>(LHSStmt), SourceLocation(), cast<Expr>(RHSStmt), Exp->getType(), VK_RValue, OK_Ordinary); return CondExpr; } else if (const ObjCIvarRefExpr *IRE = dyn_cast<ObjCIvarRefExpr>(BlockExp)) { CPT = IRE->getType()->getAs<BlockPointerType>(); } else if (const PseudoObjectExpr *POE = dyn_cast<PseudoObjectExpr>(BlockExp)) { CPT = POE->getType()->castAs<BlockPointerType>(); } else { assert(1 && "RewriteBlockClass: Bad type"); } assert(CPT && "RewriteBlockClass: Bad type"); const FunctionType *FT = CPT->getPointeeType()->getAs<FunctionType>(); assert(FT && "RewriteBlockClass: Bad type"); const FunctionProtoType *FTP = dyn_cast<FunctionProtoType>(FT); // FTP will be null for closures that don't take arguments. RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get("__block_impl")); QualType PtrBlock = Context->getPointerType(Context->getTagDeclType(RD)); // Generate a funky cast. SmallVector<QualType, 8> ArgTypes; // Push the block argument type. ArgTypes.push_back(PtrBlock); if (FTP) { for (auto &I : FTP->param_types()) { QualType t = I; // Make sure we convert "t (^)(...)" to "t (*)(...)". if (!convertBlockPointerToFunctionPointer(t)) convertToUnqualifiedObjCType(t); ArgTypes.push_back(t); } } // Now do the pointer to function cast. QualType PtrToFuncCastType = getSimpleFunctionType(Exp->getType(), ArgTypes); PtrToFuncCastType = Context->getPointerType(PtrToFuncCastType); CastExpr *BlkCast = NoTypeInfoCStyleCastExpr(Context, PtrBlock, CK_BitCast, const_cast<Expr*>(BlockExp)); // Don't forget the parens to enforce the proper binding. ParenExpr *PE = new (Context) ParenExpr(SourceLocation(), SourceLocation(), BlkCast); //PE->dump(); FieldDecl *FD = FieldDecl::Create(*Context, nullptr, SourceLocation(), SourceLocation(), &Context->Idents.get("FuncPtr"), Context->VoidPtrTy, nullptr, /*BitWidth=*/nullptr, /*Mutable=*/true, ICIS_NoInit); MemberExpr *ME = new (Context) MemberExpr(PE, true, SourceLocation(), FD, SourceLocation(), FD->getType(), VK_LValue, OK_Ordinary); CastExpr *FunkCast = NoTypeInfoCStyleCastExpr(Context, PtrToFuncCastType, CK_BitCast, ME); PE = new (Context) ParenExpr(SourceLocation(), SourceLocation(), FunkCast); SmallVector<Expr*, 8> BlkExprs; // Add the implicit argument. BlkExprs.push_back(BlkCast); // Add the user arguments. for (CallExpr::arg_iterator I = Exp->arg_begin(), E = Exp->arg_end(); I != E; ++I) { BlkExprs.push_back(*I); } CallExpr *CE = new (Context) CallExpr(*Context, PE, BlkExprs, Exp->getType(), VK_RValue, SourceLocation()); return CE; } // We need to return the rewritten expression to handle cases where the // BlockDeclRefExpr is embedded in another expression being rewritten. // For example: // // int main() { // __block Foo *f; // __block int i; // // void (^myblock)() = ^() { // [f test]; // f is a BlockDeclRefExpr embedded in a message (which is being rewritten). // i = 77; // }; //} Stmt *RewriteObjC::RewriteBlockDeclRefExpr(DeclRefExpr *DeclRefExp) { // Rewrite the byref variable into BYREFVAR->__forwarding->BYREFVAR // for each DeclRefExp where BYREFVAR is name of the variable. ValueDecl *VD = DeclRefExp->getDecl(); bool isArrow = DeclRefExp->refersToEnclosingVariableOrCapture() || HasLocalVariableExternalStorage(DeclRefExp->getDecl()); FieldDecl *FD = FieldDecl::Create(*Context, nullptr, SourceLocation(), SourceLocation(), &Context->Idents.get("__forwarding"), Context->VoidPtrTy, nullptr, /*BitWidth=*/nullptr, /*Mutable=*/true, ICIS_NoInit); MemberExpr *ME = new (Context) MemberExpr(DeclRefExp, isArrow, SourceLocation(), FD, SourceLocation(), FD->getType(), VK_LValue, OK_Ordinary); StringRef Name = VD->getName(); FD = FieldDecl::Create(*Context, nullptr, SourceLocation(), SourceLocation(), &Context->Idents.get(Name), Context->VoidPtrTy, nullptr, /*BitWidth=*/nullptr, /*Mutable=*/true, ICIS_NoInit); ME = new (Context) MemberExpr(ME, true, SourceLocation(), FD, SourceLocation(), DeclRefExp->getType(), VK_LValue, OK_Ordinary); // Need parens to enforce precedence. ParenExpr *PE = new (Context) ParenExpr(DeclRefExp->getExprLoc(), DeclRefExp->getExprLoc(), ME); ReplaceStmt(DeclRefExp, PE); return PE; } // Rewrites the imported local variable V with external storage // (static, extern, etc.) as *V // Stmt *RewriteObjC::RewriteLocalVariableExternalStorage(DeclRefExpr *DRE) { ValueDecl *VD = DRE->getDecl(); if (VarDecl *Var = dyn_cast<VarDecl>(VD)) if (!ImportedLocalExternalDecls.count(Var)) return DRE; Expr *Exp = new (Context) UnaryOperator(DRE, UO_Deref, DRE->getType(), VK_LValue, OK_Ordinary, DRE->getLocation()); // Need parens to enforce precedence. ParenExpr *PE = new (Context) ParenExpr(SourceLocation(), SourceLocation(), Exp); ReplaceStmt(DRE, PE); return PE; } void RewriteObjC::RewriteCastExpr(CStyleCastExpr *CE) { SourceLocation LocStart = CE->getLParenLoc(); SourceLocation LocEnd = CE->getRParenLoc(); // Need to avoid trying to rewrite synthesized casts. if (LocStart.isInvalid()) return; // Need to avoid trying to rewrite casts contained in macros. if (!Rewriter::isRewritable(LocStart) || !Rewriter::isRewritable(LocEnd)) return; const char *startBuf = SM->getCharacterData(LocStart); const char *endBuf = SM->getCharacterData(LocEnd); QualType QT = CE->getType(); const Type* TypePtr = QT->getAs<Type>(); if (isa<TypeOfExprType>(TypePtr)) { const TypeOfExprType *TypeOfExprTypePtr = cast<TypeOfExprType>(TypePtr); QT = TypeOfExprTypePtr->getUnderlyingExpr()->getType(); std::string TypeAsString = "("; RewriteBlockPointerType(TypeAsString, QT); TypeAsString += ")"; ReplaceText(LocStart, endBuf-startBuf+1, TypeAsString); return; } // advance the location to startArgList. const char *argPtr = startBuf; while (*argPtr++ && (argPtr < endBuf)) { switch (*argPtr) { case '^': // Replace the '^' with '*'. LocStart = LocStart.getLocWithOffset(argPtr-startBuf); ReplaceText(LocStart, 1, "*"); break; } } return; } void RewriteObjC::RewriteBlockPointerFunctionArgs(FunctionDecl *FD) { SourceLocation DeclLoc = FD->getLocation(); unsigned parenCount = 0; // We have 1 or more arguments that have closure pointers. const char *startBuf = SM->getCharacterData(DeclLoc); const char *startArgList = strchr(startBuf, '('); assert((*startArgList == '(') && "Rewriter fuzzy parser confused"); parenCount++; // advance the location to startArgList. DeclLoc = DeclLoc.getLocWithOffset(startArgList-startBuf); assert((DeclLoc.isValid()) && "Invalid DeclLoc"); const char *argPtr = startArgList; while (*argPtr++ && parenCount) { switch (*argPtr) { case '^': // Replace the '^' with '*'. DeclLoc = DeclLoc.getLocWithOffset(argPtr-startArgList); ReplaceText(DeclLoc, 1, "*"); break; case '(': parenCount++; break; case ')': parenCount--; break; } } return; } bool RewriteObjC::PointerTypeTakesAnyBlockArguments(QualType QT) { const FunctionProtoType *FTP; const PointerType *PT = QT->getAs<PointerType>(); if (PT) { FTP = PT->getPointeeType()->getAs<FunctionProtoType>(); } else { const BlockPointerType *BPT = QT->getAs<BlockPointerType>(); assert(BPT && "BlockPointerTypeTakeAnyBlockArguments(): not a block pointer type"); FTP = BPT->getPointeeType()->getAs<FunctionProtoType>(); } if (FTP) { for (const auto &I : FTP->param_types()) if (isTopLevelBlockPointerType(I)) return true; } return false; } bool RewriteObjC::PointerTypeTakesAnyObjCQualifiedType(QualType QT) { const FunctionProtoType *FTP; const PointerType *PT = QT->getAs<PointerType>(); if (PT) { FTP = PT->getPointeeType()->getAs<FunctionProtoType>(); } else { const BlockPointerType *BPT = QT->getAs<BlockPointerType>(); assert(BPT && "BlockPointerTypeTakeAnyBlockArguments(): not a block pointer type"); FTP = BPT->getPointeeType()->getAs<FunctionProtoType>(); } if (FTP) { for (const auto &I : FTP->param_types()) { if (I->isObjCQualifiedIdType()) return true; if (I->isObjCObjectPointerType() && I->getPointeeType()->isObjCQualifiedInterfaceType()) return true; } } return false; } void RewriteObjC::GetExtentOfArgList(const char *Name, const char *&LParen, const char *&RParen) { const char *argPtr = strchr(Name, '('); assert((*argPtr == '(') && "Rewriter fuzzy parser confused"); LParen = argPtr; // output the start. argPtr++; // skip past the left paren. unsigned parenCount = 1; while (*argPtr && parenCount) { switch (*argPtr) { case '(': parenCount++; break; case ')': parenCount--; break; default: break; } if (parenCount) argPtr++; } assert((*argPtr == ')') && "Rewriter fuzzy parser confused"); RParen = argPtr; // output the end } void RewriteObjC::RewriteBlockPointerDecl(NamedDecl *ND) { if (FunctionDecl *FD = dyn_cast<FunctionDecl>(ND)) { RewriteBlockPointerFunctionArgs(FD); return; } // Handle Variables and Typedefs. SourceLocation DeclLoc = ND->getLocation(); QualType DeclT; if (VarDecl *VD = dyn_cast<VarDecl>(ND)) DeclT = VD->getType(); else if (TypedefNameDecl *TDD = dyn_cast<TypedefNameDecl>(ND)) DeclT = TDD->getUnderlyingType(); else if (FieldDecl *FD = dyn_cast<FieldDecl>(ND)) DeclT = FD->getType(); else llvm_unreachable("RewriteBlockPointerDecl(): Decl type not yet handled"); const char *startBuf = SM->getCharacterData(DeclLoc); const char *endBuf = startBuf; // scan backward (from the decl location) for the end of the previous decl. while (*startBuf != '^' && *startBuf != ';' && startBuf != MainFileStart) startBuf--; SourceLocation Start = DeclLoc.getLocWithOffset(startBuf-endBuf); std::string buf; unsigned OrigLength=0; // *startBuf != '^' if we are dealing with a pointer to function that // may take block argument types (which will be handled below). if (*startBuf == '^') { // Replace the '^' with '*', computing a negative offset. buf = '*'; startBuf++; OrigLength++; } while (*startBuf != ')') { buf += *startBuf; startBuf++; OrigLength++; } buf += ')'; OrigLength++; if (PointerTypeTakesAnyBlockArguments(DeclT) || PointerTypeTakesAnyObjCQualifiedType(DeclT)) { // Replace the '^' with '*' for arguments. // Replace id<P> with id/*<>*/ DeclLoc = ND->getLocation(); startBuf = SM->getCharacterData(DeclLoc); const char *argListBegin, *argListEnd; GetExtentOfArgList(startBuf, argListBegin, argListEnd); while (argListBegin < argListEnd) { if (*argListBegin == '^') buf += '*'; else if (*argListBegin == '<') { buf += "/*"; buf += *argListBegin++; OrigLength++; while (*argListBegin != '>') { buf += *argListBegin++; OrigLength++; } buf += *argListBegin; buf += "*/"; } else buf += *argListBegin; argListBegin++; OrigLength++; } buf += ')'; OrigLength++; } ReplaceText(Start, OrigLength, buf); return; } /// SynthesizeByrefCopyDestroyHelper - This routine synthesizes: /// void __Block_byref_id_object_copy(struct Block_byref_id_object *dst, /// struct Block_byref_id_object *src) { /// _Block_object_assign (&_dest->object, _src->object, /// BLOCK_BYREF_CALLER | BLOCK_FIELD_IS_OBJECT /// [|BLOCK_FIELD_IS_WEAK]) // object /// _Block_object_assign(&_dest->object, _src->object, /// BLOCK_BYREF_CALLER | BLOCK_FIELD_IS_BLOCK /// [|BLOCK_FIELD_IS_WEAK]) // block /// } /// And: /// void __Block_byref_id_object_dispose(struct Block_byref_id_object *_src) { /// _Block_object_dispose(_src->object, /// BLOCK_BYREF_CALLER | BLOCK_FIELD_IS_OBJECT /// [|BLOCK_FIELD_IS_WEAK]) // object /// _Block_object_dispose(_src->object, /// BLOCK_BYREF_CALLER | BLOCK_FIELD_IS_BLOCK /// [|BLOCK_FIELD_IS_WEAK]) // block /// } std::string RewriteObjC::SynthesizeByrefCopyDestroyHelper(VarDecl *VD, int flag) { std::string S; if (CopyDestroyCache.count(flag)) return S; CopyDestroyCache.insert(flag); S = "static void __Block_byref_id_object_copy_"; S += utostr(flag); S += "(void *dst, void *src) {\n"; // offset into the object pointer is computed as: // void * + void* + int + int + void* + void * unsigned IntSize = static_cast<unsigned>(Context->getTypeSize(Context->IntTy)); unsigned VoidPtrSize = static_cast<unsigned>(Context->getTypeSize(Context->VoidPtrTy)); unsigned offset = (VoidPtrSize*4 + IntSize + IntSize)/Context->getCharWidth(); S += " _Block_object_assign((char*)dst + "; S += utostr(offset); S += ", *(void * *) ((char*)src + "; S += utostr(offset); S += "), "; S += utostr(flag); S += ");\n}\n"; S += "static void __Block_byref_id_object_dispose_"; S += utostr(flag); S += "(void *src) {\n"; S += " _Block_object_dispose(*(void * *) ((char*)src + "; S += utostr(offset); S += "), "; S += utostr(flag); S += ");\n}\n"; return S; } /// RewriteByRefVar - For each __block typex ND variable this routine transforms /// the declaration into: /// struct __Block_byref_ND { /// void *__isa; // NULL for everything except __weak pointers /// struct __Block_byref_ND *__forwarding; /// int32_t __flags; /// int32_t __size; /// void *__Block_byref_id_object_copy; // If variable is __block ObjC object /// void *__Block_byref_id_object_dispose; // If variable is __block ObjC object /// typex ND; /// }; /// /// It then replaces declaration of ND variable with: /// struct __Block_byref_ND ND = {__isa=0B, __forwarding=&ND, __flags=some_flag, /// __size=sizeof(struct __Block_byref_ND), /// ND=initializer-if-any}; /// /// void RewriteObjC::RewriteByRefVar(VarDecl *ND) { // Insert declaration for the function in which block literal is // used. if (CurFunctionDeclToDeclareForBlock) RewriteBlockLiteralFunctionDecl(CurFunctionDeclToDeclareForBlock); int flag = 0; int isa = 0; SourceLocation DeclLoc = ND->getTypeSpecStartLoc(); if (DeclLoc.isInvalid()) // If type location is missing, it is because of missing type (a warning). // Use variable's location which is good for this case. DeclLoc = ND->getLocation(); const char *startBuf = SM->getCharacterData(DeclLoc); SourceLocation X = ND->getLocEnd(); X = SM->getExpansionLoc(X); const char *endBuf = SM->getCharacterData(X); std::string Name(ND->getNameAsString()); std::string ByrefType; RewriteByRefString(ByrefType, Name, ND, true); ByrefType += " {\n"; ByrefType += " void *__isa;\n"; RewriteByRefString(ByrefType, Name, ND); ByrefType += " *__forwarding;\n"; ByrefType += " int __flags;\n"; ByrefType += " int __size;\n"; // Add void *__Block_byref_id_object_copy; // void *__Block_byref_id_object_dispose; if needed. QualType Ty = ND->getType(); bool HasCopyAndDispose = Context->BlockRequiresCopying(Ty, ND); if (HasCopyAndDispose) { ByrefType += " void (*__Block_byref_id_object_copy)(void*, void*);\n"; ByrefType += " void (*__Block_byref_id_object_dispose)(void*);\n"; } QualType T = Ty; (void)convertBlockPointerToFunctionPointer(T); T.getAsStringInternal(Name, Context->getPrintingPolicy()); ByrefType += " " + Name + ";\n"; ByrefType += "};\n"; // Insert this type in global scope. It is needed by helper function. SourceLocation FunLocStart; if (CurFunctionDef) FunLocStart = CurFunctionDef->getTypeSpecStartLoc(); else { assert(CurMethodDef && "RewriteByRefVar - CurMethodDef is null"); FunLocStart = CurMethodDef->getLocStart(); } InsertText(FunLocStart, ByrefType); if (Ty.isObjCGCWeak()) { flag |= BLOCK_FIELD_IS_WEAK; isa = 1; } if (HasCopyAndDispose) { flag = BLOCK_BYREF_CALLER; QualType Ty = ND->getType(); // FIXME. Handle __weak variable (BLOCK_FIELD_IS_WEAK) as well. if (Ty->isBlockPointerType()) flag |= BLOCK_FIELD_IS_BLOCK; else flag |= BLOCK_FIELD_IS_OBJECT; std::string HF = SynthesizeByrefCopyDestroyHelper(ND, flag); if (!HF.empty()) InsertText(FunLocStart, HF); } // struct __Block_byref_ND ND = // {0, &ND, some_flag, __size=sizeof(struct __Block_byref_ND), // initializer-if-any}; bool hasInit = (ND->getInit() != nullptr); unsigned flags = 0; if (HasCopyAndDispose) flags |= BLOCK_HAS_COPY_DISPOSE; Name = ND->getNameAsString(); ByrefType.clear(); RewriteByRefString(ByrefType, Name, ND); std::string ForwardingCastType("("); ForwardingCastType += ByrefType + " *)"; if (!hasInit) { ByrefType += " " + Name + " = {(void*)"; ByrefType += utostr(isa); ByrefType += "," + ForwardingCastType + "&" + Name + ", "; ByrefType += utostr(flags); ByrefType += ", "; ByrefType += "sizeof("; RewriteByRefString(ByrefType, Name, ND); ByrefType += ")"; if (HasCopyAndDispose) { ByrefType += ", __Block_byref_id_object_copy_"; ByrefType += utostr(flag); ByrefType += ", __Block_byref_id_object_dispose_"; ByrefType += utostr(flag); } ByrefType += "};\n"; unsigned nameSize = Name.size(); // for block or function pointer declaration. Name is aleady // part of the declaration. if (Ty->isBlockPointerType() || Ty->isFunctionPointerType()) nameSize = 1; ReplaceText(DeclLoc, endBuf-startBuf+nameSize, ByrefType); } else { SourceLocation startLoc; Expr *E = ND->getInit(); if (const CStyleCastExpr *ECE = dyn_cast<CStyleCastExpr>(E)) startLoc = ECE->getLParenLoc(); else startLoc = E->getLocStart(); startLoc = SM->getExpansionLoc(startLoc); endBuf = SM->getCharacterData(startLoc); ByrefType += " " + Name; ByrefType += " = {(void*)"; ByrefType += utostr(isa); ByrefType += "," + ForwardingCastType + "&" + Name + ", "; ByrefType += utostr(flags); ByrefType += ", "; ByrefType += "sizeof("; RewriteByRefString(ByrefType, Name, ND); ByrefType += "), "; if (HasCopyAndDispose) { ByrefType += "__Block_byref_id_object_copy_"; ByrefType += utostr(flag); ByrefType += ", __Block_byref_id_object_dispose_"; ByrefType += utostr(flag); ByrefType += ", "; } ReplaceText(DeclLoc, endBuf-startBuf, ByrefType); // Complete the newly synthesized compound expression by inserting a right // curly brace before the end of the declaration. // FIXME: This approach avoids rewriting the initializer expression. It // also assumes there is only one declarator. For example, the following // isn't currently supported by this routine (in general): // // double __block BYREFVAR = 1.34, BYREFVAR2 = 1.37; // const char *startInitializerBuf = SM->getCharacterData(startLoc); const char *semiBuf = strchr(startInitializerBuf, ';'); assert((*semiBuf == ';') && "RewriteByRefVar: can't find ';'"); SourceLocation semiLoc = startLoc.getLocWithOffset(semiBuf-startInitializerBuf); InsertText(semiLoc, "}"); } return; } void RewriteObjC::CollectBlockDeclRefInfo(BlockExpr *Exp) { // Add initializers for any closure decl refs. GetBlockDeclRefExprs(Exp->getBody()); if (BlockDeclRefs.size()) { // Unique all "by copy" declarations. for (unsigned i = 0; i < BlockDeclRefs.size(); i++) if (!BlockDeclRefs[i]->getDecl()->hasAttr<BlocksAttr>()) { if (!BlockByCopyDeclsPtrSet.count(BlockDeclRefs[i]->getDecl())) { BlockByCopyDeclsPtrSet.insert(BlockDeclRefs[i]->getDecl()); BlockByCopyDecls.push_back(BlockDeclRefs[i]->getDecl()); } } // Unique all "by ref" declarations. for (unsigned i = 0; i < BlockDeclRefs.size(); i++) if (BlockDeclRefs[i]->getDecl()->hasAttr<BlocksAttr>()) { if (!BlockByRefDeclsPtrSet.count(BlockDeclRefs[i]->getDecl())) { BlockByRefDeclsPtrSet.insert(BlockDeclRefs[i]->getDecl()); BlockByRefDecls.push_back(BlockDeclRefs[i]->getDecl()); } } // Find any imported blocks...they will need special attention. for (unsigned i = 0; i < BlockDeclRefs.size(); i++) if (BlockDeclRefs[i]->getDecl()->hasAttr<BlocksAttr>() || BlockDeclRefs[i]->getType()->isObjCObjectPointerType() || BlockDeclRefs[i]->getType()->isBlockPointerType()) ImportedBlockDecls.insert(BlockDeclRefs[i]->getDecl()); } } FunctionDecl *RewriteObjC::SynthBlockInitFunctionDecl(StringRef name) { IdentifierInfo *ID = &Context->Idents.get(name); QualType FType = Context->getFunctionNoProtoType(Context->VoidPtrTy); return FunctionDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), ID, FType, nullptr, SC_Extern, false, false); } Stmt *RewriteObjC::SynthBlockInitExpr(BlockExpr *Exp, const SmallVectorImpl<DeclRefExpr *> &InnerBlockDeclRefs) { const BlockDecl *block = Exp->getBlockDecl(); Blocks.push_back(Exp); CollectBlockDeclRefInfo(Exp); // Add inner imported variables now used in current block. int countOfInnerDecls = 0; if (!InnerBlockDeclRefs.empty()) { for (unsigned i = 0; i < InnerBlockDeclRefs.size(); i++) { DeclRefExpr *Exp = InnerBlockDeclRefs[i]; ValueDecl *VD = Exp->getDecl(); if (!VD->hasAttr<BlocksAttr>() && !BlockByCopyDeclsPtrSet.count(VD)) { // We need to save the copied-in variables in nested // blocks because it is needed at the end for some of the API generations. // See SynthesizeBlockLiterals routine. InnerDeclRefs.push_back(Exp); countOfInnerDecls++; BlockDeclRefs.push_back(Exp); BlockByCopyDeclsPtrSet.insert(VD); BlockByCopyDecls.push_back(VD); } if (VD->hasAttr<BlocksAttr>() && !BlockByRefDeclsPtrSet.count(VD)) { InnerDeclRefs.push_back(Exp); countOfInnerDecls++; BlockDeclRefs.push_back(Exp); BlockByRefDeclsPtrSet.insert(VD); BlockByRefDecls.push_back(VD); } } // Find any imported blocks...they will need special attention. for (unsigned i = 0; i < InnerBlockDeclRefs.size(); i++) if (InnerBlockDeclRefs[i]->getDecl()->hasAttr<BlocksAttr>() || InnerBlockDeclRefs[i]->getType()->isObjCObjectPointerType() || InnerBlockDeclRefs[i]->getType()->isBlockPointerType()) ImportedBlockDecls.insert(InnerBlockDeclRefs[i]->getDecl()); } InnerDeclRefsCount.push_back(countOfInnerDecls); std::string FuncName; if (CurFunctionDef) FuncName = CurFunctionDef->getNameAsString(); else if (CurMethodDef) BuildUniqueMethodName(FuncName, CurMethodDef); else if (GlobalVarDecl) FuncName = std::string(GlobalVarDecl->getNameAsString()); std::string BlockNumber = utostr(Blocks.size()-1); std::string Tag = "__" + FuncName + "_block_impl_" + BlockNumber; std::string Func = "__" + FuncName + "_block_func_" + BlockNumber; // Get a pointer to the function type so we can cast appropriately. QualType BFT = convertFunctionTypeOfBlocks(Exp->getFunctionType()); QualType FType = Context->getPointerType(BFT); FunctionDecl *FD; Expr *NewRep; // Simulate a constructor call... FD = SynthBlockInitFunctionDecl(Tag); DeclRefExpr *DRE = new (Context) DeclRefExpr(FD, false, FType, VK_RValue, SourceLocation()); SmallVector<Expr*, 4> InitExprs; // Initialize the block function. FD = SynthBlockInitFunctionDecl(Func); DeclRefExpr *Arg = new (Context) DeclRefExpr(FD, false, FD->getType(), VK_LValue, SourceLocation()); CastExpr *castExpr = NoTypeInfoCStyleCastExpr(Context, Context->VoidPtrTy, CK_BitCast, Arg); InitExprs.push_back(castExpr); // Initialize the block descriptor. std::string DescData = "__" + FuncName + "_block_desc_" + BlockNumber + "_DATA"; VarDecl *NewVD = VarDecl::Create(*Context, TUDecl, SourceLocation(), SourceLocation(), &Context->Idents.get(DescData.c_str()), Context->VoidPtrTy, nullptr, SC_Static); UnaryOperator *DescRefExpr = new (Context) UnaryOperator(new (Context) DeclRefExpr(NewVD, false, Context->VoidPtrTy, VK_LValue, SourceLocation()), UO_AddrOf, Context->getPointerType(Context->VoidPtrTy), VK_RValue, OK_Ordinary, SourceLocation()); InitExprs.push_back(DescRefExpr); // Add initializers for any closure decl refs. if (BlockDeclRefs.size()) { Expr *Exp; // Output all "by copy" declarations. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByCopyDecls.begin(), E = BlockByCopyDecls.end(); I != E; ++I) { if (isObjCType((*I)->getType())) { // FIXME: Conform to ABI ([[obj retain] autorelease]). FD = SynthBlockInitFunctionDecl((*I)->getName()); Exp = new (Context) DeclRefExpr(FD, false, FD->getType(), VK_LValue, SourceLocation()); if (HasLocalVariableExternalStorage(*I)) { QualType QT = (*I)->getType(); QT = Context->getPointerType(QT); Exp = new (Context) UnaryOperator(Exp, UO_AddrOf, QT, VK_RValue, OK_Ordinary, SourceLocation()); } } else if (isTopLevelBlockPointerType((*I)->getType())) { FD = SynthBlockInitFunctionDecl((*I)->getName()); Arg = new (Context) DeclRefExpr(FD, false, FD->getType(), VK_LValue, SourceLocation()); Exp = NoTypeInfoCStyleCastExpr(Context, Context->VoidPtrTy, CK_BitCast, Arg); } else { FD = SynthBlockInitFunctionDecl((*I)->getName()); Exp = new (Context) DeclRefExpr(FD, false, FD->getType(), VK_LValue, SourceLocation()); if (HasLocalVariableExternalStorage(*I)) { QualType QT = (*I)->getType(); QT = Context->getPointerType(QT); Exp = new (Context) UnaryOperator(Exp, UO_AddrOf, QT, VK_RValue, OK_Ordinary, SourceLocation()); } } InitExprs.push_back(Exp); } // Output all "by ref" declarations. for (SmallVectorImpl<ValueDecl *>::iterator I = BlockByRefDecls.begin(), E = BlockByRefDecls.end(); I != E; ++I) { ValueDecl *ND = (*I); std::string Name(ND->getNameAsString()); std::string RecName; RewriteByRefString(RecName, Name, ND, true); IdentifierInfo *II = &Context->Idents.get(RecName.c_str() + sizeof("struct")); RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), II); assert(RD && "SynthBlockInitExpr(): Can't find RecordDecl"); QualType castT = Context->getPointerType(Context->getTagDeclType(RD)); FD = SynthBlockInitFunctionDecl((*I)->getName()); Exp = new (Context) DeclRefExpr(FD, false, FD->getType(), VK_LValue, SourceLocation()); bool isNestedCapturedVar = false; if (block) for (const auto &CI : block->captures()) { const VarDecl *variable = CI.getVariable(); if (variable == ND && CI.isNested()) { assert (CI.isByRef() && "SynthBlockInitExpr - captured block variable is not byref"); isNestedCapturedVar = true; break; } } // captured nested byref variable has its address passed. Do not take // its address again. if (!isNestedCapturedVar) Exp = new (Context) UnaryOperator(Exp, UO_AddrOf, Context->getPointerType(Exp->getType()), VK_RValue, OK_Ordinary, SourceLocation()); Exp = NoTypeInfoCStyleCastExpr(Context, castT, CK_BitCast, Exp); InitExprs.push_back(Exp); } } if (ImportedBlockDecls.size()) { // generate BLOCK_HAS_COPY_DISPOSE(have helper funcs) | BLOCK_HAS_DESCRIPTOR int flag = (BLOCK_HAS_COPY_DISPOSE | BLOCK_HAS_DESCRIPTOR); unsigned IntSize = static_cast<unsigned>(Context->getTypeSize(Context->IntTy)); Expr *FlagExp = IntegerLiteral::Create(*Context, llvm::APInt(IntSize, flag), Context->IntTy, SourceLocation()); InitExprs.push_back(FlagExp); } NewRep = new (Context) CallExpr(*Context, DRE, InitExprs, FType, VK_LValue, SourceLocation()); NewRep = new (Context) UnaryOperator(NewRep, UO_AddrOf, Context->getPointerType(NewRep->getType()), VK_RValue, OK_Ordinary, SourceLocation()); NewRep = NoTypeInfoCStyleCastExpr(Context, FType, CK_BitCast, NewRep); BlockDeclRefs.clear(); BlockByRefDecls.clear(); BlockByRefDeclsPtrSet.clear(); BlockByCopyDecls.clear(); BlockByCopyDeclsPtrSet.clear(); ImportedBlockDecls.clear(); return NewRep; } bool RewriteObjC::IsDeclStmtInForeachHeader(DeclStmt *DS) { if (const ObjCForCollectionStmt * CS = dyn_cast<ObjCForCollectionStmt>(Stmts.back())) return CS->getElement() == DS; return false; } //===----------------------------------------------------------------------===// // Function Body / Expression rewriting //===----------------------------------------------------------------------===// Stmt *RewriteObjC::RewriteFunctionBodyOrGlobalInitializer(Stmt *S) { if (isa<SwitchStmt>(S) || isa<WhileStmt>(S) || isa<DoStmt>(S) || isa<ForStmt>(S)) Stmts.push_back(S); else if (isa<ObjCForCollectionStmt>(S)) { Stmts.push_back(S); ObjCBcLabelNo.push_back(++BcLabelCount); } // Pseudo-object operations and ivar references need special // treatment because we're going to recursively rewrite them. if (PseudoObjectExpr *PseudoOp = dyn_cast<PseudoObjectExpr>(S)) { if (isa<BinaryOperator>(PseudoOp->getSyntacticForm())) { return RewritePropertyOrImplicitSetter(PseudoOp); } else { return RewritePropertyOrImplicitGetter(PseudoOp); } } else if (ObjCIvarRefExpr *IvarRefExpr = dyn_cast<ObjCIvarRefExpr>(S)) { return RewriteObjCIvarRefExpr(IvarRefExpr); } SourceRange OrigStmtRange = S->getSourceRange(); // Perform a bottom up rewrite of all children. for (Stmt::child_range CI = S->children(); CI; ++CI) if (*CI) { Stmt *childStmt = (*CI); Stmt *newStmt = RewriteFunctionBodyOrGlobalInitializer(childStmt); if (newStmt) { *CI = newStmt; } } if (BlockExpr *BE = dyn_cast<BlockExpr>(S)) { SmallVector<DeclRefExpr *, 8> InnerBlockDeclRefs; llvm::SmallPtrSet<const DeclContext *, 8> InnerContexts; InnerContexts.insert(BE->getBlockDecl()); ImportedLocalExternalDecls.clear(); GetInnerBlockDeclRefExprs(BE->getBody(), InnerBlockDeclRefs, InnerContexts); // Rewrite the block body in place. Stmt *SaveCurrentBody = CurrentBody; CurrentBody = BE->getBody(); PropParentMap = nullptr; // block literal on rhs of a property-dot-sytax assignment // must be replaced by its synthesize ast so getRewrittenText // works as expected. In this case, what actually ends up on RHS // is the blockTranscribed which is the helper function for the // block literal; as in: self.c = ^() {[ace ARR];}; bool saveDisableReplaceStmt = DisableReplaceStmt; DisableReplaceStmt = false; RewriteFunctionBodyOrGlobalInitializer(BE->getBody()); DisableReplaceStmt = saveDisableReplaceStmt; CurrentBody = SaveCurrentBody; PropParentMap = nullptr; ImportedLocalExternalDecls.clear(); // Now we snarf the rewritten text and stash it away for later use. std::string Str = Rewrite.getRewrittenText(BE->getSourceRange()); RewrittenBlockExprs[BE] = Str; Stmt *blockTranscribed = SynthBlockInitExpr(BE, InnerBlockDeclRefs); //blockTranscribed->dump(); ReplaceStmt(S, blockTranscribed); return blockTranscribed; } // Handle specific things. if (ObjCEncodeExpr *AtEncode = dyn_cast<ObjCEncodeExpr>(S)) return RewriteAtEncode(AtEncode); if (ObjCSelectorExpr *AtSelector = dyn_cast<ObjCSelectorExpr>(S)) return RewriteAtSelector(AtSelector); if (ObjCStringLiteral *AtString = dyn_cast<ObjCStringLiteral>(S)) return RewriteObjCStringLiteral(AtString); if (ObjCMessageExpr *MessExpr = dyn_cast<ObjCMessageExpr>(S)) { #if 0 // Before we rewrite it, put the original message expression in a comment. SourceLocation startLoc = MessExpr->getLocStart(); SourceLocation endLoc = MessExpr->getLocEnd(); const char *startBuf = SM->getCharacterData(startLoc); const char *endBuf = SM->getCharacterData(endLoc); std::string messString; messString += "// "; messString.append(startBuf, endBuf-startBuf+1); messString += "\n"; // FIXME: Missing definition of // InsertText(clang::SourceLocation, char const*, unsigned int). // InsertText(startLoc, messString.c_str(), messString.size()); // Tried this, but it didn't work either... // ReplaceText(startLoc, 0, messString.c_str(), messString.size()); #endif return RewriteMessageExpr(MessExpr); } if (ObjCAtTryStmt *StmtTry = dyn_cast<ObjCAtTryStmt>(S)) return RewriteObjCTryStmt(StmtTry); if (ObjCAtSynchronizedStmt *StmtTry = dyn_cast<ObjCAtSynchronizedStmt>(S)) return RewriteObjCSynchronizedStmt(StmtTry); if (ObjCAtThrowStmt *StmtThrow = dyn_cast<ObjCAtThrowStmt>(S)) return RewriteObjCThrowStmt(StmtThrow); if (ObjCProtocolExpr *ProtocolExp = dyn_cast<ObjCProtocolExpr>(S)) return RewriteObjCProtocolExpr(ProtocolExp); if (ObjCForCollectionStmt *StmtForCollection = dyn_cast<ObjCForCollectionStmt>(S)) return RewriteObjCForCollectionStmt(StmtForCollection, OrigStmtRange.getEnd()); if (BreakStmt *StmtBreakStmt = dyn_cast<BreakStmt>(S)) return RewriteBreakStmt(StmtBreakStmt); if (ContinueStmt *StmtContinueStmt = dyn_cast<ContinueStmt>(S)) return RewriteContinueStmt(StmtContinueStmt); // Need to check for protocol refs (id <P>, Foo <P> *) in variable decls // and cast exprs. if (DeclStmt *DS = dyn_cast<DeclStmt>(S)) { // FIXME: What we're doing here is modifying the type-specifier that // precedes the first Decl. In the future the DeclGroup should have // a separate type-specifier that we can rewrite. // NOTE: We need to avoid rewriting the DeclStmt if it is within // the context of an ObjCForCollectionStmt. For example: // NSArray *someArray; // for (id <FooProtocol> index in someArray) ; // This is because RewriteObjCForCollectionStmt() does textual rewriting // and it depends on the original text locations/positions. if (Stmts.empty() || !IsDeclStmtInForeachHeader(DS)) RewriteObjCQualifiedInterfaceTypes(*DS->decl_begin()); // Blocks rewrite rules. for (auto *SD : DS->decls()) { if (ValueDecl *ND = dyn_cast<ValueDecl>(SD)) { if (isTopLevelBlockPointerType(ND->getType())) RewriteBlockPointerDecl(ND); else if (ND->getType()->isFunctionPointerType()) CheckFunctionPointerDecl(ND->getType(), ND); if (VarDecl *VD = dyn_cast<VarDecl>(SD)) { if (VD->hasAttr<BlocksAttr>()) { static unsigned uniqueByrefDeclCount = 0; assert(!BlockByRefDeclNo.count(ND) && "RewriteFunctionBodyOrGlobalInitializer: Duplicate byref decl"); BlockByRefDeclNo[ND] = uniqueByrefDeclCount++; RewriteByRefVar(VD); } else RewriteTypeOfDecl(VD); } } if (TypedefNameDecl *TD = dyn_cast<TypedefNameDecl>(SD)) { if (isTopLevelBlockPointerType(TD->getUnderlyingType())) RewriteBlockPointerDecl(TD); else if (TD->getUnderlyingType()->isFunctionPointerType()) CheckFunctionPointerDecl(TD->getUnderlyingType(), TD); } } } if (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(S)) RewriteObjCQualifiedInterfaceTypes(CE); if (isa<SwitchStmt>(S) || isa<WhileStmt>(S) || isa<DoStmt>(S) || isa<ForStmt>(S)) { assert(!Stmts.empty() && "Statement stack is empty"); assert ((isa<SwitchStmt>(Stmts.back()) || isa<WhileStmt>(Stmts.back()) || isa<DoStmt>(Stmts.back()) || isa<ForStmt>(Stmts.back())) && "Statement stack mismatch"); Stmts.pop_back(); } // Handle blocks rewriting. if (DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(S)) { ValueDecl *VD = DRE->getDecl(); if (VD->hasAttr<BlocksAttr>()) return RewriteBlockDeclRefExpr(DRE); if (HasLocalVariableExternalStorage(VD)) return RewriteLocalVariableExternalStorage(DRE); } if (CallExpr *CE = dyn_cast<CallExpr>(S)) { if (CE->getCallee()->getType()->isBlockPointerType()) { Stmt *BlockCall = SynthesizeBlockCall(CE, CE->getCallee()); ReplaceStmt(S, BlockCall); return BlockCall; } } if (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(S)) { RewriteCastExpr(CE); } #if 0 if (ImplicitCastExpr *ICE = dyn_cast<ImplicitCastExpr>(S)) { CastExpr *Replacement = new (Context) CastExpr(ICE->getType(), ICE->getSubExpr(), SourceLocation()); // Get the new text. std::string SStr; llvm::raw_string_ostream Buf(SStr); Replacement->printPretty(Buf); const std::string &Str = Buf.str(); printf("CAST = %s\n", &Str[0]); InsertText(ICE->getSubExpr()->getLocStart(), &Str[0], Str.size()); delete S; return Replacement; } #endif // Return this stmt unmodified. return S; } void RewriteObjC::RewriteRecordBody(RecordDecl *RD) { for (auto *FD : RD->fields()) { if (isTopLevelBlockPointerType(FD->getType())) RewriteBlockPointerDecl(FD); if (FD->getType()->isObjCQualifiedIdType() || FD->getType()->isObjCQualifiedInterfaceType()) RewriteObjCQualifiedInterfaceTypes(FD); } } /// HandleDeclInMainFile - This is called for each top-level decl defined in the /// main file of the input. void RewriteObjC::HandleDeclInMainFile(Decl *D) { switch (D->getKind()) { case Decl::Function: { FunctionDecl *FD = cast<FunctionDecl>(D); if (FD->isOverloadedOperator()) return; // Since function prototypes don't have ParmDecl's, we check the function // prototype. This enables us to rewrite function declarations and // definitions using the same code. RewriteBlocksInFunctionProtoType(FD->getType(), FD); if (!FD->isThisDeclarationADefinition()) break; // FIXME: If this should support Obj-C++, support CXXTryStmt if (CompoundStmt *Body = dyn_cast_or_null<CompoundStmt>(FD->getBody())) { CurFunctionDef = FD; CurFunctionDeclToDeclareForBlock = FD; CurrentBody = Body; Body = cast_or_null<CompoundStmt>(RewriteFunctionBodyOrGlobalInitializer(Body)); FD->setBody(Body); CurrentBody = nullptr; if (PropParentMap) { delete PropParentMap; PropParentMap = nullptr; } // This synthesizes and inserts the block "impl" struct, invoke function, // and any copy/dispose helper functions. InsertBlockLiteralsWithinFunction(FD); CurFunctionDef = nullptr; CurFunctionDeclToDeclareForBlock = nullptr; } break; } case Decl::ObjCMethod: { ObjCMethodDecl *MD = cast<ObjCMethodDecl>(D); if (CompoundStmt *Body = MD->getCompoundBody()) { CurMethodDef = MD; CurrentBody = Body; Body = cast_or_null<CompoundStmt>(RewriteFunctionBodyOrGlobalInitializer(Body)); MD->setBody(Body); CurrentBody = nullptr; if (PropParentMap) { delete PropParentMap; PropParentMap = nullptr; } InsertBlockLiteralsWithinMethod(MD); CurMethodDef = nullptr; } break; } case Decl::ObjCImplementation: { ObjCImplementationDecl *CI = cast<ObjCImplementationDecl>(D); ClassImplementation.push_back(CI); break; } case Decl::ObjCCategoryImpl: { ObjCCategoryImplDecl *CI = cast<ObjCCategoryImplDecl>(D); CategoryImplementation.push_back(CI); break; } case Decl::Var: { VarDecl *VD = cast<VarDecl>(D); RewriteObjCQualifiedInterfaceTypes(VD); if (isTopLevelBlockPointerType(VD->getType())) RewriteBlockPointerDecl(VD); else if (VD->getType()->isFunctionPointerType()) { CheckFunctionPointerDecl(VD->getType(), VD); if (VD->getInit()) { if (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(VD->getInit())) { RewriteCastExpr(CE); } } } else if (VD->getType()->isRecordType()) { RecordDecl *RD = VD->getType()->getAs<RecordType>()->getDecl(); if (RD->isCompleteDefinition()) RewriteRecordBody(RD); } if (VD->getInit()) { GlobalVarDecl = VD; CurrentBody = VD->getInit(); RewriteFunctionBodyOrGlobalInitializer(VD->getInit()); CurrentBody = nullptr; if (PropParentMap) { delete PropParentMap; PropParentMap = nullptr; } SynthesizeBlockLiterals(VD->getTypeSpecStartLoc(), VD->getName()); GlobalVarDecl = nullptr; // This is needed for blocks. if (CStyleCastExpr *CE = dyn_cast<CStyleCastExpr>(VD->getInit())) { RewriteCastExpr(CE); } } break; } case Decl::TypeAlias: case Decl::Typedef: { if (TypedefNameDecl *TD = dyn_cast<TypedefNameDecl>(D)) { if (isTopLevelBlockPointerType(TD->getUnderlyingType())) RewriteBlockPointerDecl(TD); else if (TD->getUnderlyingType()->isFunctionPointerType()) CheckFunctionPointerDecl(TD->getUnderlyingType(), TD); } break; } case Decl::CXXRecord: case Decl::Record: { RecordDecl *RD = cast<RecordDecl>(D); if (RD->isCompleteDefinition()) RewriteRecordBody(RD); break; } default: break; } // Nothing yet. } void RewriteObjC::HandleTranslationUnit(ASTContext &C) { if (Diags.hasErrorOccurred()) return; RewriteInclude(); // Here's a great place to add any extra declarations that may be needed. // Write out meta data for each @protocol(<expr>). for (ObjCProtocolDecl *ProtDecl : ProtocolExprDecls) RewriteObjCProtocolMetaData(ProtDecl, "", "", Preamble); InsertText(SM->getLocForStartOfFile(MainFileID), Preamble, false); if (ClassImplementation.size() || CategoryImplementation.size()) RewriteImplementations(); // Get the buffer corresponding to MainFileID. If we haven't changed it, then // we are done. if (const RewriteBuffer *RewriteBuf = Rewrite.getRewriteBufferFor(MainFileID)) { //printf("Changed:\n"); *OutFile << std::string(RewriteBuf->begin(), RewriteBuf->end()); } else { llvm::errs() << "No changes\n"; } if (ClassImplementation.size() || CategoryImplementation.size() || ProtocolExprDecls.size()) { // Rewrite Objective-c meta data* std::string ResultStr; RewriteMetaDataIntoBuffer(ResultStr); // Emit metadata. *OutFile << ResultStr; } OutFile->flush(); } void RewriteObjCFragileABI::Initialize(ASTContext &context) { InitializeCommon(context); // declaring objc_selector outside the parameter list removes a silly // scope related warning... if (IsHeader) Preamble = "#pragma once\n"; Preamble += "struct objc_selector; struct objc_class;\n"; Preamble += "struct __rw_objc_super { struct objc_object *object; "; Preamble += "struct objc_object *superClass; "; if (LangOpts.MicrosoftExt) { // Add a constructor for creating temporary objects. Preamble += "__rw_objc_super(struct objc_object *o, struct objc_object *s) " ": "; Preamble += "object(o), superClass(s) {} "; } Preamble += "};\n"; Preamble += "#ifndef _REWRITER_typedef_Protocol\n"; Preamble += "typedef struct objc_object Protocol;\n"; Preamble += "#define _REWRITER_typedef_Protocol\n"; Preamble += "#endif\n"; if (LangOpts.MicrosoftExt) { Preamble += "#define __OBJC_RW_DLLIMPORT extern \"C\" __declspec(dllimport)\n"; Preamble += "#define __OBJC_RW_STATICIMPORT extern \"C\"\n"; } else Preamble += "#define __OBJC_RW_DLLIMPORT extern\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object *objc_msgSend"; Preamble += "(struct objc_object *, struct objc_selector *, ...);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object *objc_msgSendSuper"; Preamble += "(struct objc_super *, struct objc_selector *, ...);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object* objc_msgSend_stret"; Preamble += "(struct objc_object *, struct objc_selector *, ...);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object* objc_msgSendSuper_stret"; Preamble += "(struct objc_super *, struct objc_selector *, ...);\n"; Preamble += "__OBJC_RW_DLLIMPORT double objc_msgSend_fpret"; Preamble += "(struct objc_object *, struct objc_selector *, ...);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object *objc_getClass"; Preamble += "(const char *);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_class *class_getSuperclass"; Preamble += "(struct objc_class *);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object *objc_getMetaClass"; Preamble += "(const char *);\n"; Preamble += "__OBJC_RW_DLLIMPORT void objc_exception_throw(struct objc_object *);\n"; Preamble += "__OBJC_RW_DLLIMPORT void objc_exception_try_enter(void *);\n"; Preamble += "__OBJC_RW_DLLIMPORT void objc_exception_try_exit(void *);\n"; Preamble += "__OBJC_RW_DLLIMPORT struct objc_object *objc_exception_extract(void *);\n"; Preamble += "__OBJC_RW_DLLIMPORT int objc_exception_match"; Preamble += "(struct objc_class *, struct objc_object *);\n"; // @synchronized hooks. Preamble += "__OBJC_RW_DLLIMPORT int objc_sync_enter(struct objc_object *);\n"; Preamble += "__OBJC_RW_DLLIMPORT int objc_sync_exit(struct objc_object *);\n"; Preamble += "__OBJC_RW_DLLIMPORT Protocol *objc_getProtocol(const char *);\n"; Preamble += "#ifndef __FASTENUMERATIONSTATE\n"; Preamble += "struct __objcFastEnumerationState {\n\t"; Preamble += "unsigned long state;\n\t"; Preamble += "void **itemsPtr;\n\t"; Preamble += "unsigned long *mutationsPtr;\n\t"; Preamble += "unsigned long extra[5];\n};\n"; Preamble += "__OBJC_RW_DLLIMPORT void objc_enumerationMutation(struct objc_object *);\n"; Preamble += "#define __FASTENUMERATIONSTATE\n"; Preamble += "#endif\n"; Preamble += "#ifndef __NSCONSTANTSTRINGIMPL\n"; Preamble += "struct __NSConstantStringImpl {\n"; Preamble += " int *isa;\n"; Preamble += " int flags;\n"; Preamble += " char *str;\n"; Preamble += " long length;\n"; Preamble += "};\n"; Preamble += "#ifdef CF_EXPORT_CONSTANT_STRING\n"; Preamble += "extern \"C\" __declspec(dllexport) int __CFConstantStringClassReference[];\n"; Preamble += "#else\n"; Preamble += "__OBJC_RW_DLLIMPORT int __CFConstantStringClassReference[];\n"; Preamble += "#endif\n"; Preamble += "#define __NSCONSTANTSTRINGIMPL\n"; Preamble += "#endif\n"; // Blocks preamble. Preamble += "#ifndef BLOCK_IMPL\n"; Preamble += "#define BLOCK_IMPL\n"; Preamble += "struct __block_impl {\n"; Preamble += " void *isa;\n"; Preamble += " int Flags;\n"; Preamble += " int Reserved;\n"; Preamble += " void *FuncPtr;\n"; Preamble += "};\n"; Preamble += "// Runtime copy/destroy helper functions (from Block_private.h)\n"; Preamble += "#ifdef __OBJC_EXPORT_BLOCKS\n"; Preamble += "extern \"C\" __declspec(dllexport) " "void _Block_object_assign(void *, const void *, const int);\n"; Preamble += "extern \"C\" __declspec(dllexport) void _Block_object_dispose(const void *, const int);\n"; Preamble += "extern \"C\" __declspec(dllexport) void *_NSConcreteGlobalBlock[32];\n"; Preamble += "extern \"C\" __declspec(dllexport) void *_NSConcreteStackBlock[32];\n"; Preamble += "#else\n"; Preamble += "__OBJC_RW_DLLIMPORT void _Block_object_assign(void *, const void *, const int);\n"; Preamble += "__OBJC_RW_DLLIMPORT void _Block_object_dispose(const void *, const int);\n"; Preamble += "__OBJC_RW_DLLIMPORT void *_NSConcreteGlobalBlock[32];\n"; Preamble += "__OBJC_RW_DLLIMPORT void *_NSConcreteStackBlock[32];\n"; Preamble += "#endif\n"; Preamble += "#endif\n"; if (LangOpts.MicrosoftExt) { Preamble += "#undef __OBJC_RW_DLLIMPORT\n"; Preamble += "#undef __OBJC_RW_STATICIMPORT\n"; Preamble += "#ifndef KEEP_ATTRIBUTES\n"; // We use this for clang tests. Preamble += "#define __attribute__(X)\n"; Preamble += "#endif\n"; Preamble += "#define __weak\n"; } else { Preamble += "#define __block\n"; Preamble += "#define __weak\n"; } // NOTE! Windows uses LLP64 for 64bit mode. So, cast pointer to long long // as this avoids warning in any 64bit/32bit compilation model. Preamble += "\n#define __OFFSETOFIVAR__(TYPE, MEMBER) ((long long) &((TYPE *)0)->MEMBER)\n"; } /// RewriteIvarOffsetComputation - This rutine synthesizes computation of /// ivar offset. void RewriteObjCFragileABI::RewriteIvarOffsetComputation(ObjCIvarDecl *ivar, std::string &Result) { if (ivar->isBitField()) { // FIXME: The hack below doesn't work for bitfields. For now, we simply // place all bitfields at offset 0. Result += "0"; } else { Result += "__OFFSETOFIVAR__(struct "; Result += ivar->getContainingInterface()->getNameAsString(); if (LangOpts.MicrosoftExt) Result += "_IMPL"; Result += ", "; Result += ivar->getNameAsString(); Result += ")"; } } /// RewriteObjCProtocolMetaData - Rewrite protocols meta-data. void RewriteObjCFragileABI::RewriteObjCProtocolMetaData( ObjCProtocolDecl *PDecl, StringRef prefix, StringRef ClassName, std::string &Result) { static bool objc_protocol_methods = false; // Output struct protocol_methods holder of method selector and type. if (!objc_protocol_methods && PDecl->hasDefinition()) { /* struct protocol_methods { SEL _cmd; char *method_types; } */ Result += "\nstruct _protocol_methods {\n"; Result += "\tstruct objc_selector *_cmd;\n"; Result += "\tchar *method_types;\n"; Result += "};\n"; objc_protocol_methods = true; } // Do not synthesize the protocol more than once. if (ObjCSynthesizedProtocols.count(PDecl->getCanonicalDecl())) return; if (ObjCProtocolDecl *Def = PDecl->getDefinition()) PDecl = Def; if (PDecl->instmeth_begin() != PDecl->instmeth_end()) { unsigned NumMethods = std::distance(PDecl->instmeth_begin(), PDecl->instmeth_end()); /* struct _objc_protocol_method_list { int protocol_method_count; struct protocol_methods protocols[]; } */ Result += "\nstatic struct {\n"; Result += "\tint protocol_method_count;\n"; Result += "\tstruct _protocol_methods protocol_methods["; Result += utostr(NumMethods); Result += "];\n} _OBJC_PROTOCOL_INSTANCE_METHODS_"; Result += PDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __cat_inst_meth\")))= " "{\n\t" + utostr(NumMethods) + "\n"; // Output instance methods declared in this protocol. for (ObjCProtocolDecl::instmeth_iterator I = PDecl->instmeth_begin(), E = PDecl->instmeth_end(); I != E; ++I) { if (I == PDecl->instmeth_begin()) Result += "\t ,{{(struct objc_selector *)\""; else Result += "\t ,{(struct objc_selector *)\""; Result += (*I)->getSelector().getAsString(); std::string MethodTypeString; Context->getObjCEncodingForMethodDecl((*I), MethodTypeString); Result += "\", \""; Result += MethodTypeString; Result += "\"}\n"; } Result += "\t }\n};\n"; } // Output class methods declared in this protocol. unsigned NumMethods = std::distance(PDecl->classmeth_begin(), PDecl->classmeth_end()); if (NumMethods > 0) { /* struct _objc_protocol_method_list { int protocol_method_count; struct protocol_methods protocols[]; } */ Result += "\nstatic struct {\n"; Result += "\tint protocol_method_count;\n"; Result += "\tstruct _protocol_methods protocol_methods["; Result += utostr(NumMethods); Result += "];\n} _OBJC_PROTOCOL_CLASS_METHODS_"; Result += PDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __cat_cls_meth\")))= " "{\n\t"; Result += utostr(NumMethods); Result += "\n"; // Output instance methods declared in this protocol. for (ObjCProtocolDecl::classmeth_iterator I = PDecl->classmeth_begin(), E = PDecl->classmeth_end(); I != E; ++I) { if (I == PDecl->classmeth_begin()) Result += "\t ,{{(struct objc_selector *)\""; else Result += "\t ,{(struct objc_selector *)\""; Result += (*I)->getSelector().getAsString(); std::string MethodTypeString; Context->getObjCEncodingForMethodDecl((*I), MethodTypeString); Result += "\", \""; Result += MethodTypeString; Result += "\"}\n"; } Result += "\t }\n};\n"; } // Output: /* struct _objc_protocol { // Objective-C 1.0 extensions struct _objc_protocol_extension *isa; char *protocol_name; struct _objc_protocol **protocol_list; struct _objc_protocol_method_list *instance_methods; struct _objc_protocol_method_list *class_methods; }; */ static bool objc_protocol = false; if (!objc_protocol) { Result += "\nstruct _objc_protocol {\n"; Result += "\tstruct _objc_protocol_extension *isa;\n"; Result += "\tchar *protocol_name;\n"; Result += "\tstruct _objc_protocol **protocol_list;\n"; Result += "\tstruct _objc_protocol_method_list *instance_methods;\n"; Result += "\tstruct _objc_protocol_method_list *class_methods;\n"; Result += "};\n"; objc_protocol = true; } Result += "\nstatic struct _objc_protocol _OBJC_PROTOCOL_"; Result += PDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __protocol\")))= " "{\n\t0, \""; Result += PDecl->getNameAsString(); Result += "\", 0, "; if (PDecl->instmeth_begin() != PDecl->instmeth_end()) { Result += "(struct _objc_protocol_method_list *)&_OBJC_PROTOCOL_INSTANCE_METHODS_"; Result += PDecl->getNameAsString(); Result += ", "; } else Result += "0, "; if (PDecl->classmeth_begin() != PDecl->classmeth_end()) { Result += "(struct _objc_protocol_method_list *)&_OBJC_PROTOCOL_CLASS_METHODS_"; Result += PDecl->getNameAsString(); Result += "\n"; } else Result += "0\n"; Result += "};\n"; // Mark this protocol as having been generated. if (!ObjCSynthesizedProtocols.insert(PDecl->getCanonicalDecl()).second) llvm_unreachable("protocol already synthesized"); } void RewriteObjCFragileABI::RewriteObjCProtocolListMetaData( const ObjCList<ObjCProtocolDecl> &Protocols, StringRef prefix, StringRef ClassName, std::string &Result) { if (Protocols.empty()) return; for (unsigned i = 0; i != Protocols.size(); i++) RewriteObjCProtocolMetaData(Protocols[i], prefix, ClassName, Result); // Output the top lovel protocol meta-data for the class. /* struct _objc_protocol_list { struct _objc_protocol_list *next; int protocol_count; struct _objc_protocol *class_protocols[]; } */ Result += "\nstatic struct {\n"; Result += "\tstruct _objc_protocol_list *next;\n"; Result += "\tint protocol_count;\n"; Result += "\tstruct _objc_protocol *class_protocols["; Result += utostr(Protocols.size()); Result += "];\n} _OBJC_"; Result += prefix; Result += "_PROTOCOLS_"; Result += ClassName; Result += " __attribute__ ((used, section (\"__OBJC, __cat_cls_meth\")))= " "{\n\t0, "; Result += utostr(Protocols.size()); Result += "\n"; Result += "\t,{&_OBJC_PROTOCOL_"; Result += Protocols[0]->getNameAsString(); Result += " \n"; for (unsigned i = 1; i != Protocols.size(); i++) { Result += "\t ,&_OBJC_PROTOCOL_"; Result += Protocols[i]->getNameAsString(); Result += "\n"; } Result += "\t }\n};\n"; } void RewriteObjCFragileABI::RewriteObjCClassMetaData(ObjCImplementationDecl *IDecl, std::string &Result) { ObjCInterfaceDecl *CDecl = IDecl->getClassInterface(); // Explicitly declared @interface's are already synthesized. if (CDecl->isImplicitInterfaceDecl()) { // FIXME: Implementation of a class with no @interface (legacy) does not // produce correct synthesis as yet. RewriteObjCInternalStruct(CDecl, Result); } // Build _objc_ivar_list metadata for classes ivars if needed unsigned NumIvars = !IDecl->ivar_empty() ? IDecl->ivar_size() : (CDecl ? CDecl->ivar_size() : 0); if (NumIvars > 0) { static bool objc_ivar = false; if (!objc_ivar) { /* struct _objc_ivar { char *ivar_name; char *ivar_type; int ivar_offset; }; */ Result += "\nstruct _objc_ivar {\n"; Result += "\tchar *ivar_name;\n"; Result += "\tchar *ivar_type;\n"; Result += "\tint ivar_offset;\n"; Result += "};\n"; objc_ivar = true; } /* struct { int ivar_count; struct _objc_ivar ivar_list[nIvars]; }; */ Result += "\nstatic struct {\n"; Result += "\tint ivar_count;\n"; Result += "\tstruct _objc_ivar ivar_list["; Result += utostr(NumIvars); Result += "];\n} _OBJC_INSTANCE_VARIABLES_"; Result += IDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __instance_vars\")))= " "{\n\t"; Result += utostr(NumIvars); Result += "\n"; ObjCInterfaceDecl::ivar_iterator IVI, IVE; SmallVector<ObjCIvarDecl *, 8> IVars; if (!IDecl->ivar_empty()) { for (auto *IV : IDecl->ivars()) IVars.push_back(IV); IVI = IDecl->ivar_begin(); IVE = IDecl->ivar_end(); } else { IVI = CDecl->ivar_begin(); IVE = CDecl->ivar_end(); } Result += "\t,{{\""; Result += IVI->getNameAsString(); Result += "\", \""; std::string TmpString, StrEncoding; Context->getObjCEncodingForType(IVI->getType(), TmpString, *IVI); QuoteDoublequotes(TmpString, StrEncoding); Result += StrEncoding; Result += "\", "; RewriteIvarOffsetComputation(*IVI, Result); Result += "}\n"; for (++IVI; IVI != IVE; ++IVI) { Result += "\t ,{\""; Result += IVI->getNameAsString(); Result += "\", \""; std::string TmpString, StrEncoding; Context->getObjCEncodingForType(IVI->getType(), TmpString, *IVI); QuoteDoublequotes(TmpString, StrEncoding); Result += StrEncoding; Result += "\", "; RewriteIvarOffsetComputation(*IVI, Result); Result += "}\n"; } Result += "\t }\n};\n"; } // Build _objc_method_list for class's instance methods if needed SmallVector<ObjCMethodDecl *, 32> InstanceMethods(IDecl->instance_methods()); // If any of our property implementations have associated getters or // setters, produce metadata for them as well. for (const auto *Prop : IDecl->property_impls()) { if (Prop->getPropertyImplementation() == ObjCPropertyImplDecl::Dynamic) continue; if (!Prop->getPropertyIvarDecl()) continue; ObjCPropertyDecl *PD = Prop->getPropertyDecl(); if (!PD) continue; if (ObjCMethodDecl *Getter = PD->getGetterMethodDecl()) if (!Getter->isDefined()) InstanceMethods.push_back(Getter); if (PD->isReadOnly()) continue; if (ObjCMethodDecl *Setter = PD->getSetterMethodDecl()) if (!Setter->isDefined()) InstanceMethods.push_back(Setter); } RewriteObjCMethodsMetaData(InstanceMethods.begin(), InstanceMethods.end(), true, "", IDecl->getName(), Result); // Build _objc_method_list for class's class methods if needed RewriteObjCMethodsMetaData(IDecl->classmeth_begin(), IDecl->classmeth_end(), false, "", IDecl->getName(), Result); // Protocols referenced in class declaration? RewriteObjCProtocolListMetaData(CDecl->getReferencedProtocols(), "CLASS", CDecl->getName(), Result); // Declaration of class/meta-class metadata /* struct _objc_class { struct _objc_class *isa; // or const char *root_class_name when metadata const char *super_class_name; char *name; long version; long info; long instance_size; struct _objc_ivar_list *ivars; struct _objc_method_list *methods; struct objc_cache *cache; struct objc_protocol_list *protocols; const char *ivar_layout; struct _objc_class_ext *ext; }; */ static bool objc_class = false; if (!objc_class) { Result += "\nstruct _objc_class {\n"; Result += "\tstruct _objc_class *isa;\n"; Result += "\tconst char *super_class_name;\n"; Result += "\tchar *name;\n"; Result += "\tlong version;\n"; Result += "\tlong info;\n"; Result += "\tlong instance_size;\n"; Result += "\tstruct _objc_ivar_list *ivars;\n"; Result += "\tstruct _objc_method_list *methods;\n"; Result += "\tstruct objc_cache *cache;\n"; Result += "\tstruct _objc_protocol_list *protocols;\n"; Result += "\tconst char *ivar_layout;\n"; Result += "\tstruct _objc_class_ext *ext;\n"; Result += "};\n"; objc_class = true; } // Meta-class metadata generation. ObjCInterfaceDecl *RootClass = nullptr; ObjCInterfaceDecl *SuperClass = CDecl->getSuperClass(); while (SuperClass) { RootClass = SuperClass; SuperClass = SuperClass->getSuperClass(); } SuperClass = CDecl->getSuperClass(); Result += "\nstatic struct _objc_class _OBJC_METACLASS_"; Result += CDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __meta_class\")))= " "{\n\t(struct _objc_class *)\""; Result += (RootClass ? RootClass->getNameAsString() : CDecl->getNameAsString()); Result += "\""; if (SuperClass) { Result += ", \""; Result += SuperClass->getNameAsString(); Result += "\", \""; Result += CDecl->getNameAsString(); Result += "\""; } else { Result += ", 0, \""; Result += CDecl->getNameAsString(); Result += "\""; } // Set 'ivars' field for root class to 0. ObjC1 runtime does not use it. // 'info' field is initialized to CLS_META(2) for metaclass Result += ", 0,2, sizeof(struct _objc_class), 0"; if (IDecl->classmeth_begin() != IDecl->classmeth_end()) { Result += "\n\t, (struct _objc_method_list *)&_OBJC_CLASS_METHODS_"; Result += IDecl->getNameAsString(); Result += "\n"; } else Result += ", 0\n"; if (CDecl->protocol_begin() != CDecl->protocol_end()) { Result += "\t,0, (struct _objc_protocol_list *)&_OBJC_CLASS_PROTOCOLS_"; Result += CDecl->getNameAsString(); Result += ",0,0\n"; } else Result += "\t,0,0,0,0\n"; Result += "};\n"; // class metadata generation. Result += "\nstatic struct _objc_class _OBJC_CLASS_"; Result += CDecl->getNameAsString(); Result += " __attribute__ ((used, section (\"__OBJC, __class\")))= " "{\n\t&_OBJC_METACLASS_"; Result += CDecl->getNameAsString(); if (SuperClass) { Result += ", \""; Result += SuperClass->getNameAsString(); Result += "\", \""; Result += CDecl->getNameAsString(); Result += "\""; } else { Result += ", 0, \""; Result += CDecl->getNameAsString(); Result += "\""; } // 'info' field is initialized to CLS_CLASS(1) for class Result += ", 0,1"; if (!ObjCSynthesizedStructs.count(CDecl)) Result += ",0"; else { // class has size. Must synthesize its size. Result += ",sizeof(struct "; Result += CDecl->getNameAsString(); if (LangOpts.MicrosoftExt) Result += "_IMPL"; Result += ")"; } if (NumIvars > 0) { Result += ", (struct _objc_ivar_list *)&_OBJC_INSTANCE_VARIABLES_"; Result += CDecl->getNameAsString(); Result += "\n\t"; } else Result += ",0"; if (IDecl->instmeth_begin() != IDecl->instmeth_end()) { Result += ", (struct _objc_method_list *)&_OBJC_INSTANCE_METHODS_"; Result += CDecl->getNameAsString(); Result += ", 0\n\t"; } else Result += ",0,0"; if (CDecl->protocol_begin() != CDecl->protocol_end()) { Result += ", (struct _objc_protocol_list*)&_OBJC_CLASS_PROTOCOLS_"; Result += CDecl->getNameAsString(); Result += ", 0,0\n"; } else Result += ",0,0,0\n"; Result += "};\n"; } void RewriteObjCFragileABI::RewriteMetaDataIntoBuffer(std::string &Result) { int ClsDefCount = ClassImplementation.size(); int CatDefCount = CategoryImplementation.size(); // For each implemented class, write out all its meta data. for (int i = 0; i < ClsDefCount; i++) RewriteObjCClassMetaData(ClassImplementation[i], Result); // For each implemented category, write out all its meta data. for (int i = 0; i < CatDefCount; i++) RewriteObjCCategoryImplDecl(CategoryImplementation[i], Result); // Write objc_symtab metadata /* struct _objc_symtab { long sel_ref_cnt; SEL *refs; short cls_def_cnt; short cat_def_cnt; void *defs[cls_def_cnt + cat_def_cnt]; }; */ Result += "\nstruct _objc_symtab {\n"; Result += "\tlong sel_ref_cnt;\n"; Result += "\tSEL *refs;\n"; Result += "\tshort cls_def_cnt;\n"; Result += "\tshort cat_def_cnt;\n"; Result += "\tvoid *defs[" + utostr(ClsDefCount + CatDefCount)+ "];\n"; Result += "};\n\n"; Result += "static struct _objc_symtab " "_OBJC_SYMBOLS __attribute__((used, section (\"__OBJC, __symbols\")))= {\n"; Result += "\t0, 0, " + utostr(ClsDefCount) + ", " + utostr(CatDefCount) + "\n"; for (int i = 0; i < ClsDefCount; i++) { Result += "\t,&_OBJC_CLASS_"; Result += ClassImplementation[i]->getNameAsString(); Result += "\n"; } for (int i = 0; i < CatDefCount; i++) { Result += "\t,&_OBJC_CATEGORY_"; Result += CategoryImplementation[i]->getClassInterface()->getNameAsString(); Result += "_"; Result += CategoryImplementation[i]->getNameAsString(); Result += "\n"; } Result += "};\n\n"; // Write objc_module metadata /* struct _objc_module { long version; long size; const char *name; struct _objc_symtab *symtab; } */ Result += "\nstruct _objc_module {\n"; Result += "\tlong version;\n"; Result += "\tlong size;\n"; Result += "\tconst char *name;\n"; Result += "\tstruct _objc_symtab *symtab;\n"; Result += "};\n\n"; Result += "static struct _objc_module " "_OBJC_MODULES __attribute__ ((used, section (\"__OBJC, __module_info\")))= {\n"; Result += "\t" + utostr(OBJC_ABI_VERSION) + ", sizeof(struct _objc_module), \"\", &_OBJC_SYMBOLS\n"; Result += "};\n\n"; if (LangOpts.MicrosoftExt) { if (ProtocolExprDecls.size()) { Result += "#pragma section(\".objc_protocol$B\",long,read,write)\n"; Result += "#pragma data_seg(push, \".objc_protocol$B\")\n"; for (ObjCProtocolDecl *ProtDecl : ProtocolExprDecls) { Result += "static struct _objc_protocol *_POINTER_OBJC_PROTOCOL_"; Result += ProtDecl->getNameAsString(); Result += " = &_OBJC_PROTOCOL_"; Result += ProtDecl->getNameAsString(); Result += ";\n"; } Result += "#pragma data_seg(pop)\n\n"; } Result += "#pragma section(\".objc_module_info$B\",long,read,write)\n"; Result += "#pragma data_seg(push, \".objc_module_info$B\")\n"; Result += "static struct _objc_module *_POINTER_OBJC_MODULES = "; Result += "&_OBJC_MODULES;\n"; Result += "#pragma data_seg(pop)\n\n"; } } /// RewriteObjCCategoryImplDecl - Rewrite metadata for each category /// implementation. void RewriteObjCFragileABI::RewriteObjCCategoryImplDecl(ObjCCategoryImplDecl *IDecl, std::string &Result) { ObjCInterfaceDecl *ClassDecl = IDecl->getClassInterface(); // Find category declaration for this implementation. ObjCCategoryDecl *CDecl = ClassDecl->FindCategoryDeclaration(IDecl->getIdentifier()); std::string FullCategoryName = ClassDecl->getNameAsString(); FullCategoryName += '_'; FullCategoryName += IDecl->getNameAsString(); // Build _objc_method_list for class's instance methods if needed SmallVector<ObjCMethodDecl *, 32> InstanceMethods(IDecl->instance_methods()); // If any of our property implementations have associated getters or // setters, produce metadata for them as well. for (const auto *Prop : IDecl->property_impls()) { if (Prop->getPropertyImplementation() == ObjCPropertyImplDecl::Dynamic) continue; if (!Prop->getPropertyIvarDecl()) continue; ObjCPropertyDecl *PD = Prop->getPropertyDecl(); if (!PD) continue; if (ObjCMethodDecl *Getter = PD->getGetterMethodDecl()) InstanceMethods.push_back(Getter); if (PD->isReadOnly()) continue; if (ObjCMethodDecl *Setter = PD->getSetterMethodDecl()) InstanceMethods.push_back(Setter); } RewriteObjCMethodsMetaData(InstanceMethods.begin(), InstanceMethods.end(), true, "CATEGORY_", FullCategoryName.c_str(), Result); // Build _objc_method_list for class's class methods if needed RewriteObjCMethodsMetaData(IDecl->classmeth_begin(), IDecl->classmeth_end(), false, "CATEGORY_", FullCategoryName.c_str(), Result); // Protocols referenced in class declaration? // Null CDecl is case of a category implementation with no category interface if (CDecl) RewriteObjCProtocolListMetaData(CDecl->getReferencedProtocols(), "CATEGORY", FullCategoryName, Result); /* struct _objc_category { char *category_name; char *class_name; struct _objc_method_list *instance_methods; struct _objc_method_list *class_methods; struct _objc_protocol_list *protocols; // Objective-C 1.0 extensions uint32_t size; // sizeof (struct _objc_category) struct _objc_property_list *instance_properties; // category's own // @property decl. }; */ static bool objc_category = false; if (!objc_category) { Result += "\nstruct _objc_category {\n"; Result += "\tchar *category_name;\n"; Result += "\tchar *class_name;\n"; Result += "\tstruct _objc_method_list *instance_methods;\n"; Result += "\tstruct _objc_method_list *class_methods;\n"; Result += "\tstruct _objc_protocol_list *protocols;\n"; Result += "\tunsigned int size;\n"; Result += "\tstruct _objc_property_list *instance_properties;\n"; Result += "};\n"; objc_category = true; } Result += "\nstatic struct _objc_category _OBJC_CATEGORY_"; Result += FullCategoryName; Result += " __attribute__ ((used, section (\"__OBJC, __category\")))= {\n\t\""; Result += IDecl->getNameAsString(); Result += "\"\n\t, \""; Result += ClassDecl->getNameAsString(); Result += "\"\n"; if (IDecl->instmeth_begin() != IDecl->instmeth_end()) { Result += "\t, (struct _objc_method_list *)" "&_OBJC_CATEGORY_INSTANCE_METHODS_"; Result += FullCategoryName; Result += "\n"; } else Result += "\t, 0\n"; if (IDecl->classmeth_begin() != IDecl->classmeth_end()) { Result += "\t, (struct _objc_method_list *)" "&_OBJC_CATEGORY_CLASS_METHODS_"; Result += FullCategoryName; Result += "\n"; } else Result += "\t, 0\n"; if (CDecl && CDecl->protocol_begin() != CDecl->protocol_end()) { Result += "\t, (struct _objc_protocol_list *)&_OBJC_CATEGORY_PROTOCOLS_"; Result += FullCategoryName; Result += "\n"; } else Result += "\t, 0\n"; Result += "\t, sizeof(struct _objc_category), 0\n};\n"; } // RewriteObjCMethodsMetaData - Rewrite methods metadata for instance or /// class methods. template<typename MethodIterator> void RewriteObjCFragileABI::RewriteObjCMethodsMetaData(MethodIterator MethodBegin, MethodIterator MethodEnd, bool IsInstanceMethod, StringRef prefix, StringRef ClassName, std::string &Result) { if (MethodBegin == MethodEnd) return; if (!objc_impl_method) { /* struct _objc_method { SEL _cmd; char *method_types; void *_imp; } */ Result += "\nstruct _objc_method {\n"; Result += "\tSEL _cmd;\n"; Result += "\tchar *method_types;\n"; Result += "\tvoid *_imp;\n"; Result += "};\n"; objc_impl_method = true; } // Build _objc_method_list for class's methods if needed /* struct { struct _objc_method_list *next_method; int method_count; struct _objc_method method_list[]; } */ unsigned NumMethods = std::distance(MethodBegin, MethodEnd); Result += "\nstatic struct {\n"; Result += "\tstruct _objc_method_list *next_method;\n"; Result += "\tint method_count;\n"; Result += "\tstruct _objc_method method_list["; Result += utostr(NumMethods); Result += "];\n} _OBJC_"; Result += prefix; Result += IsInstanceMethod ? "INSTANCE" : "CLASS"; Result += "_METHODS_"; Result += ClassName; Result += " __attribute__ ((used, section (\"__OBJC, __"; Result += IsInstanceMethod ? "inst" : "cls"; Result += "_meth\")))= "; Result += "{\n\t0, " + utostr(NumMethods) + "\n"; Result += "\t,{{(SEL)\""; Result += (*MethodBegin)->getSelector().getAsString().c_str(); std::string MethodTypeString; Context->getObjCEncodingForMethodDecl(*MethodBegin, MethodTypeString); Result += "\", \""; Result += MethodTypeString; Result += "\", (void *)"; Result += MethodInternalNames[*MethodBegin]; Result += "}\n"; for (++MethodBegin; MethodBegin != MethodEnd; ++MethodBegin) { Result += "\t ,{(SEL)\""; Result += (*MethodBegin)->getSelector().getAsString().c_str(); std::string MethodTypeString; Context->getObjCEncodingForMethodDecl(*MethodBegin, MethodTypeString); Result += "\", \""; Result += MethodTypeString; Result += "\", (void *)"; Result += MethodInternalNames[*MethodBegin]; Result += "}\n"; } Result += "\t }\n};\n"; } Stmt *RewriteObjCFragileABI::RewriteObjCIvarRefExpr(ObjCIvarRefExpr *IV) { SourceRange OldRange = IV->getSourceRange(); Expr *BaseExpr = IV->getBase(); // Rewrite the base, but without actually doing replaces. { DisableReplaceStmtScope S(*this); BaseExpr = cast<Expr>(RewriteFunctionBodyOrGlobalInitializer(BaseExpr)); IV->setBase(BaseExpr); } ObjCIvarDecl *D = IV->getDecl(); Expr *Replacement = IV; if (CurMethodDef) { if (BaseExpr->getType()->isObjCObjectPointerType()) { const ObjCInterfaceType *iFaceDecl = dyn_cast<ObjCInterfaceType>(BaseExpr->getType()->getPointeeType()); assert(iFaceDecl && "RewriteObjCIvarRefExpr - iFaceDecl is null"); // lookup which class implements the instance variable. ObjCInterfaceDecl *clsDeclared = nullptr; iFaceDecl->getDecl()->lookupInstanceVariable(D->getIdentifier(), clsDeclared); assert(clsDeclared && "RewriteObjCIvarRefExpr(): Can't find class"); // Synthesize an explicit cast to gain access to the ivar. std::string RecName = clsDeclared->getIdentifier()->getName(); RecName += "_IMPL"; IdentifierInfo *II = &Context->Idents.get(RecName); RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), II); assert(RD && "RewriteObjCIvarRefExpr(): Can't find RecordDecl"); QualType castT = Context->getPointerType(Context->getTagDeclType(RD)); CastExpr *castExpr = NoTypeInfoCStyleCastExpr(Context, castT, CK_BitCast, IV->getBase()); // Don't forget the parens to enforce the proper binding. ParenExpr *PE = new (Context) ParenExpr(OldRange.getBegin(), OldRange.getEnd(), castExpr); if (IV->isFreeIvar() && declaresSameEntity(CurMethodDef->getClassInterface(), iFaceDecl->getDecl())) { MemberExpr *ME = new (Context) MemberExpr(PE, true, SourceLocation(), D, IV->getLocation(), D->getType(), VK_LValue, OK_Ordinary); Replacement = ME; } else { IV->setBase(PE); } } } else { // we are outside a method. assert(!IV->isFreeIvar() && "Cannot have a free standing ivar outside a method"); // Explicit ivar refs need to have a cast inserted. // FIXME: consider sharing some of this code with the code above. if (BaseExpr->getType()->isObjCObjectPointerType()) { const ObjCInterfaceType *iFaceDecl = dyn_cast<ObjCInterfaceType>(BaseExpr->getType()->getPointeeType()); // lookup which class implements the instance variable. ObjCInterfaceDecl *clsDeclared = nullptr; iFaceDecl->getDecl()->lookupInstanceVariable(D->getIdentifier(), clsDeclared); assert(clsDeclared && "RewriteObjCIvarRefExpr(): Can't find class"); // Synthesize an explicit cast to gain access to the ivar. std::string RecName = clsDeclared->getIdentifier()->getName(); RecName += "_IMPL"; IdentifierInfo *II = &Context->Idents.get(RecName); RecordDecl *RD = RecordDecl::Create(*Context, TTK_Struct, TUDecl, SourceLocation(), SourceLocation(), II); assert(RD && "RewriteObjCIvarRefExpr(): Can't find RecordDecl"); QualType castT = Context->getPointerType(Context->getTagDeclType(RD)); CastExpr *castExpr = NoTypeInfoCStyleCastExpr(Context, castT, CK_BitCast, IV->getBase()); // Don't forget the parens to enforce the proper binding. ParenExpr *PE = new (Context) ParenExpr(IV->getBase()->getLocStart(), IV->getBase()->getLocEnd(), castExpr); // Cannot delete IV->getBase(), since PE points to it. // Replace the old base with the cast. This is important when doing // embedded rewrites. For example, [newInv->_container addObject:0]. IV->setBase(PE); } } ReplaceStmtWithRange(IV, Replacement, OldRange); return Replacement; } #endif